"","X","ROW","WOS","AUTHORS","YEAR","TITLE","JOURNAL","SYS","COMMENTS","EXCLUDE","DATA.SOURCE","EXP.TIME","EXP.YEAR","LAB.FIELD","HABITAT","LATITUDE","LONGITUDE","SITE","SUBJECT","ORGANISM","DURATION","EXP.UNIT.TYPE","CONTAINER.TYPE","SIZE.VOL","SIZE.AREA","HERB.PRS","OTHER.TRTS","LIGHT.TRT.TYPE","DAYLENGTH","LIGHT.AMBIENT","WAVELENGTH","TEMP","PH","CON","SAL","SRP","DIN","TP","TN","SI","MEAS_NUT","Light.CON.s","Light.CON.d","Light.REG.CON","INI.BM.CON","BM.CON","BM.MEASURE","RESP.CAT","RESPONSE.TYPE","RESP.TYP2","INI.BM.CON.SD","BM.CON.SD","INI.BM.CON.STE","BM.CON.STE","BM.CON.N","Light.TRT.s","Light.TRT.d","Light.REG.TRT","INI.BM.TRT","BM.TRT","BM.MEASURE.TRT","RESPONSE.TYPE.TRT","INI.BM.TRT.SD","BM.TRT.SD","INI.BM.TRT.STE","BM.TRT.STE","BM.TRT.N","J","pooledSD","d","var.d"
"1",1,2,"1","Guevara, M et al",2016,"Comparison of growth and biochemical parameters of two strains of Rhodomonas salina (Cryptophyceae) cultivated under different combinations of irradiance, temperature, and nutrients","JOURNAL OF APPLIED PHYCOLOGY",1,"Intraspecific comparison of 2 strains of Rhodomonas",NA,"Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Rhodomonas salina (CS-174) (Cryptophyceae)","phytoplankton",10,"microcosm","Erlenmeyer flask",0.5,NA,"no","nut_temp",NA,NA,NA,NA,19,NA,NA,33,18,441,18,441,NA,4,200,NA,100,NA,1040000,"cell /mL","abundance","biom","SS",NA,190000,NA,95000,4,100,NA,50,NA,1100000,"cell /mL",2,NA,1140000,NA,570000,4,0.87,817220.9,0.064,0.5
"2",2,3,"1","Guevara, M et al",2016,"Comparison of growth and biochemical parameters of two strains of Rhodomonas salina (Cryptophyceae) cultivated under different combinations of irradiance, temperature, and nutrients","JOURNAL OF APPLIED PHYCOLOGY",1,"Intraspecific comparison of 2 strains of Rhodomonas",NA,"Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Rhodomonas salina (CS-24) Cryptophyceae","phytoplankton",10,"microcosm","Erlenmeyer flask",0.5,NA,"no","nut_temp",NA,NA,NA,NA,19,NA,NA,33,18,441,18,441,NA,4,200,NA,100,NA,1060000,"cell /mL","abundance","biom","SS",NA,40000,NA,20000,4,100,NA,50,NA,1110000,"cell /mL",2,NA,1160000,NA,580000,4,0.87,820731.381,0.053,0.5
"3",3,4,"3","Rock, AM",2016,"Carnivore identity mediates the effects of light and nutrients on aquatic food-chain efficiency","FRESHWATER BIOLOGY",2,NA,"freshwater study, no irradiance values given, zooplankton included,","Fig 4ef, Table 1","summer","2010","Field",NA,NA,NA,NA,NA,NA,NA,NA,NA,5000,NA,"yes","nutrients",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"4",4,5,"7","Thrane, JE",2016,"The impact of irradiance on optimal and cellular nitrogen to phosphorus ratios in phytoplankton","ECOLOGY LETTERS",2,NA,"freshwater study, no STD given","Fig 4a",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,NA,NA,1.073,"Growth rate (µ/d)","growth rate","biom","dSS",NA,NA,NA,NA,NA,20,NA,NA,NA,0.401,"Growth rate (µ/d)",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"5",5,6,"8","Ptacnik, R",2016,"A light-induced shortcut in the planktonic microbial loop","SCIENTIFIC REPORTS",1,"mixotrophs","bacteria and zooplankton study",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"6",6,7,"10","Orefice, I",2016,"Light-induced changes in the photosynthetic physiology and biochemistry in the diatom Skeletonema marinoi","ALGAL RESEARCH-Biomass BIOFUELS AND BIOPRODUCTS",1,"Fluctuating red light peaks superimposed on blue sinusoidal light and blue square-wave light. TRT value given as average","pulsed monochromatic light","Table 1",NA,"2015","Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1,"microcosm","glass flask",4.5,NA,"no","interval","Fluctuating, sinusoidal, square-wave light",NA,150,"422-496, 590-656",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0.65,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.08,NA,0.046,3,80,NA,53.3,NA,0.45,"Growth rate (µ/d)",NA,NA,0.04,NA,0.023,3,0.8,0.063,-2.53,1.2
"7",7,8,"10","Orefice, I",2016,"Light-induced changes in the photosynthetic physiology and biochemistry in the diatom Skeletonema marinoi","ALGAL RESEARCH-Biomass BIOFUELS AND BIOPRODUCTS",1,"Fluctuating red light peaks superimposed on blue sinusoidal light and blue square-wave light","pulsed monochromatic light","Fig 3a",NA,"2015","Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1,"microcosm","glass flask",4.5,NA,"no","interval","Fluctuating, sinusoidal, square-wave light",NA,150,"422-496, 590-656",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0.066,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.008,NA,0.005,3,80,NA,53.3,NA,0.087,"Chl a (pg/cell)",NA,NA,0.01,NA,0.006,3,0.8,0.009,1.764,0.926
"8",8,9,"13","Tatsumi, M & Wright, JT",2016,"Understory algae and low light reduce recruitment of the habitat-forming kelp Ecklonia radiata","MARINE ECOLOGY PROGRESS SERIES",1,"kelp, ecklonia radiata","No actual light treatment",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"9",9,10,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass",NA,"Fig 2a, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,17.06,"Net community production (mmol O2/h/m2)","area-specific production","biom","dSS",NA,3.18,NA,1.59,4,163,NA,34.7,NA,10.883,"Net community production (mmol O2/h/m2)",1,NA,2.264,NA,1.132,4,0.87,2.76,-1.946,0.737
"10",10,11,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass",NA,"Fig 2a, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,17.06,"Net community production (mmol O2/h/m2)","area-specific production","biom","dSS",NA,3.18,NA,1.59,4,114,NA,24.3,NA,9.83,"Net community production (mmol O2/h/m2)",1,NA,4.7,NA,2.35,4,0.87,4.013,-1.567,0.653
"11",11,12,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"Chl a values only measured for sediment microphytobenthos",NA,"Fig 2b, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","microphytobenthos","phytobenthos",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,39.36,"Chl a (mg/m2)","biomass","biom","SS",NA,21.1,NA,10.55,4,163,NA,34.7,NA,25.8,"Chl a (mg/m2)",2,NA,14.28,NA,7.14,4,0.87,18.016,-0.655,0.527
"12",12,13,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"Chl a values only measured for sediment microphytobenthos",NA,"Fig 2b, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","microphytobenthos","phytobenthos",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,39.36,"Chl a (mg/m2)","biomass","biom","SS",NA,21.1,NA,10.55,4,114,NA,24.3,NA,29.23,"Chl a (mg/m2)",2,NA,17.82,NA,8.91,4,0.87,19.529,-0.451,0.513
"13",13,14,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass, shoot Biomass",NA,"Fig 3f, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii, shoots","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,52.07,"Shoot Biomass (C g/m2)","biomass","biom","SS",NA,13.47,NA,6.735,4,163,NA,34.7,NA,35.58,"Shoot Biomass (C g/m2)",2,NA,2.9,NA,1.45,4,0.87,9.743,-1.472,0.635
"14",14,15,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass, shoot Biomass",NA,"Fig 3f, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii, shoots","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,52.07,"Shoot Biomass (C g/m2)","biomass","biom","SS",NA,13.47,NA,6.735,4,114,NA,24.3,NA,24.65,"Shoot Biomass (C g/m2)",2,NA,3.1,NA,1.55,4,0.87,9.774,-2.44,0.872
"15",15,16,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass, rhizome Biomass",NA,"Fig 3d, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii, shoots","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,48.508,"Rhizome Biomass (C g/m2)","biomass","biom","SS",NA,10.716,NA,5.36,4,163,NA,34.7,NA,40.188,"Rhizome Biomass (C g/m2)",2,NA,12.126,NA,6.063,4,0.87,11.443,-0.632,0.525
"16",16,17,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass, rhizome Biomass",NA,"Fig 3d, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii, shoots","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,48.508,"Rhizome Biomass (C g/m2)","biomass","biom","SS",NA,10.716,NA,5.36,4,114,NA,24.3,NA,30.035,"Rhizome Biomass (C g/m2)",2,NA,5.076,NA,2.538,4,0.87,8.384,-1.916,0.729
"17",17,18,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass, root Biomass",NA,"Fig 3e, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii, shoots","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,62.045,"Root Biomass (C g/m2)","biomass","biom","SS",NA,9.024,NA,4.51,4,163,NA,34.7,NA,53.584,"Root Biomass (C g/m2)",2,NA,11.28,NA,5.64,4,0.87,10.214,-0.72,0.532
"18",18,19,"16","Dahl, M",2016,"Effects of shading and simulated grazing on carbon sequestration in a tropical seagrass meadow","JOURNAL OF ECOLOGY",1,"seagrass, root Biomass",NA,"Fig 3e, supporting data","fall","2013-2014","Field","coastal",-6.09,39.26,"Chwaka Bay, Tanzania","Thalassia hemprichii, shoots","seagrass",150,"field plot","no container",NA,10,"yes","herbivory","shading screen",NA,470,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,470,NA,100,NA,62.045,"Root Biomass (C g/m2)","biomass","biom","SS",NA,9.024,NA,4.51,4,114,NA,24.3,NA,29.471,"Root Biomass (C g/m2)",2,NA,7.614,NA,3.807,4,0.87,8.349,-3.393,1.219
"19",19,20,"18","Poulton, AJ",2016,"Production of dissolved organic carbon by Arctic plankton communities: Responses to elevated carbon dioxide and the availability of light and nutrients","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,NA,"No actual light treatment, just CO²","Table 3, figure 4","summer","2012","Field","offshore",60.35,-18.51,"Iceland basin","Total phytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",4.2,NA,"unknown","nutrients",NA,NA,NA,"PAR",10.6,8.14,NA,35.2,NA,NA,NA,NA,1.6,1,100,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,18,NA,NA,NA,NA
"20",20,21,"25","Wojciechowski, J",2016,"Morpho-physiological responses of a subtropical strain of Cylindrospermopsis raciborskii (Cyanobacteria) to different light intensities","ACTA BOTANICA BRASILICA",NA,NA,"no STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"21",21,22,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","picophytoplankton","phytoplankton",2,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.077,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0.006,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"22",22,26,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",2,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.109,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"23",23,30,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control","no STD or STE given","Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","picophytoplankton","phytoplankton",2,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,NA,NA,2.5,3,88,NA,100,NA,0.713,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,18,NA,20.5,NA,0.581,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"24",24,34,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control","no STD or STE given","Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",2,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,NA,NA,2.5,3,88,NA,100,NA,0.049,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,18,NA,20.5,NA,0,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"25",25,38,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control",NA,"Fig 3, 7ab, Landry et al 2016","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","picophytoplankton","phytoplankton",2,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,0.3,1.7,2.9,5,123,NA,100,NA,0.257,"Chl a (µg/L)","biomass","biom","SS",NA,0.049,NA,0.035,2,25,NA,20.3,NA,0.332,"Chl a (µg/L)",2,NA,0,NA,0,2,0.571,0.035,1.237,1.191
"26",26,42,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control","no STD or STE given","Fig 3, 7ab, Landry et al 2020","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",2,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,NA,NA,2.9,3,123,NA,100,NA,0.378,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,25,NA,20.3,NA,0.36,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"27",27,23,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","picophytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.222,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0.032,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"28",28,27,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.43,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0.055,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"29",29,31,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control","no STD or STE given","Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","picophytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,NA,NA,2.5,3,88,NA,100,NA,0.072,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,18,NA,20.5,NA,0.049,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"30",30,35,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control","no STD or STE given","Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,NA,NA,2.5,3,88,NA,100,NA,1.005,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,18,NA,20.5,NA,0.75,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"31",31,39,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control","no STD or STE given","Fig 3, 7ab, Landry et al 2017","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","picophytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,NA,NA,2.9,3,123,NA,100,NA,0.271,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,25,NA,20.3,NA,0.138,"Chl a (µg/L)",2,NA,0.03,NA,0.021,2,0.571,NA,NA,NA
"32",32,43,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control",NA,"Fig 3, 7ab, Landry et al 2016","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",4,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,0.3,1.7,2.9,5,123,NA,100,NA,1.165,"Chl a (µg/L)","biomass","biom","SS",NA,0.144,NA,0.102,2,25,NA,20.3,NA,0.281,"Chl a (µg/L)",2,NA,0,NA,0,2,0.571,0.102,-4.961,4.076
"33",33,24,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","picophytoplankton","phytoplankton",6,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.047,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0.068,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"34",34,28,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",6,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.062,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0.75,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"35",35,32,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control","no STD or STE given","Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","picophytoplankton","phytoplankton",6,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,NA,NA,2.5,3,88,NA,100,NA,0.064,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,18,NA,20.5,NA,0.166,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"36",36,36,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control","no STD or STE given","Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",6,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,NA,NA,2.5,3,88,NA,100,NA,0.585,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,18,NA,20.5,NA,1.05,"Chl a (µg/L)",2,NA,0.042,NA,0.03,2,0.571,NA,NA,NA
"37",37,40,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control","no STD or STE given","Fig 3, 7ab, Landry et al 2018","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","picophytoplankton","phytoplankton",6,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,NA,NA,2.9,3,123,NA,100,NA,0.052,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,25,NA,20.3,NA,0.008,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"38",38,44,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control","no STD or STE given","Fig 3, 7ab, Landry et al 2022","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",6,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,NA,NA,2.9,3,123,NA,100,NA,0.966,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,25,NA,20.3,NA,0.058,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"39",39,25,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","picophytoplankton","phytoplankton",8,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,0.464,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0.377,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"40",40,29,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 12m. TRT 20% of control","no STD or STE given","Fig 3, 5ab, Landry et al 2016","summer","2010","Field","offshore",9.04,-90.56,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",8,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,290,"PAR",27,NA,NA,33.67,0.4,2.5,NA,NA,3.3,3,290,NA,100,NA,1.156,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,58,NA,20,NA,0,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"41",41,33,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control",NA,"Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","picophytoplankton","phytoplankton",8,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,0.3,1.4,2.5,5,88,NA,100,NA,1.143,"Chl a (µg/L)","biomass","biom","SS",NA,0.151,NA,0.107,2,18,NA,20.5,NA,0.536,"Chl a (µg/L)",2,NA,0.2,NA,0.141,2,0.571,0.177,-1.957,1.479
"42",42,37,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 20m. TRT 20% of control",NA,"Fig 3, 6ab, Lnadry et al 2016","summer","2010","Field","offshore",10.42,-92.92,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",8,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,88,"PAR",28,NA,NA,33.7,0.3,1.4,0.3,1.4,2.5,5,88,NA,100,NA,0.319,"Chl a (µg/L)","biomass","biom","SS",NA,0.127,NA,0.09,2,18,NA,20.5,NA,1.249,"Chl a (µg/L)",2,NA,0.146,NA,0.103,2,0.571,0.137,3.884,2.886
"43",43,41,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control","no STD or STE given","Fig 3, 7ab, Landry et al 2019","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","picophytoplankton","phytoplankton",8,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,NA,NA,2.9,3,123,NA,100,NA,0.089,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,25,NA,20.3,NA,0,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"44",44,45,"33","Goes et al",2016,"Biological response of Costa Rica Dome phytoplankton to Light, Silicic acid and Trace metals","JOURNAL OF PLANKTON RESEARCH",1,"PAR used for light treatment measured at sample depth, 15m. TRT 20% of control","no STD or STE given","Fig 3, 7ab, Landry et al 2023","summer","2010","Field","offshore",8.55,-90.4,"Costa Rica Dome","nano+microphytoplankton","phytoplankton",8,"in situ incubation","Nalgene bottles",1,NA,"no","nutrients","shading screen",NA,123,"PAR",27.3,NA,NA,33.6,0.3,1.7,NA,NA,2.9,3,123,NA,100,NA,0.466,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,2,25,NA,20.3,NA,0.015,"Chl a (µg/L)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"45",45,46,"35","Lin, CJ",2016,"COMPETITION OF TWO PHYTOPLANKTON SPECIES FOR LIGHT WITH WAVELENGTH","DISCRETE AND CONTINUOUS DYNAMICAL SYSTEMS-SERIES B",1,NA,"pdf not available (not even on Scihub)",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"46",46,47,"42","Wu, HY",2016,"Effect of Different Light Qualities on Growth, Pigment Content, Chlorophyll Fluorescence, and Antioxidant Enzyme Activity in the Red Alga Pyropia haitanensis (Bangiales, Rhodophyta)","BIOMED RESEARCH INTERNATIONAL",1,NA,"Light treatment only with different light spectra (B,G,R), no trt for light intensity",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"47",47,48,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Chlorella vulgaris","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","24",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,1350,"mgdw/L","biomass","biom","SS",NA,130,NA,91.924,2,36,NA,20,NA,828,"mgdw/L",2,NA,23,NA,16.263,2,0.571,93.351,-3.195,2.276
"48",48,49,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Chlorella vulgaris","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","10",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,771,"mgdw/L","biomass","biom","SS",NA,11,NA,7.778,2,36,NA,20,NA,414,"mgdw/L",2,NA,13,NA,9.192,2,0.571,12.042,-16.941,36.876
"49",49,50,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Chlorella vulgaris","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","14",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,1080,"mgdw/L","biomass","biom","SS",NA,140,NA,98.995,2,36,NA,20,NA,517,"mgdw/L",2,NA,11,NA,7.778,2,0.571,99.3,-3.24,2.312
"50",50,51,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Pseudokirchneriella subcapitata","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","24",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,798,"mgdw/L","biomass","biom","SS",NA,36,NA,25.456,2,36,NA,20,NA,426,"mgdw/L",2,NA,15,NA,10.607,2,0.571,27.577,-7.708,8.427
"51",51,52,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Pseudokirchneriella subcapitata","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","10",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,488,"mgdw/L","biomass","biom","SS",NA,13,NA,9.192,2,36,NA,20,NA,234,"mgdw/L",2,NA,25,NA,17.678,2,0.571,19.925,-7.285,7.633
"52",52,53,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Pseudokirchneriella subcapitata","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","14",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,697,"mgdw/L","biomass","biom","SS",NA,7,NA,4.95,2,36,NA,20,NA,249,"mgdw/L",2,NA,13,NA,9.192,2,0.571,10.44,-24.52,76.156
"53",53,54,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Synechocystis salina","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","24",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,1260,"mgdw/L","biomass","biom","SS",NA,60,NA,42.426,2,36,NA,20,NA,738,"mgdw/L",2,NA,16,NA,11.314,2,0.571,43.909,-6.793,6.769
"54",54,55,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Synechocystis salina","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","10",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,719,"mgdw/L","biomass","biom","SS",NA,39,NA,27.577,2,36,NA,20,NA,426,"mgdw/L",2,NA,24,NA,16.971,2,0.571,32.381,-5.171,4.342
"55",55,56,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Synechocystis salina","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","14",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,914,"mgdw/L","biomass","biom","SS",NA,30,NA,21.213,2,36,NA,20,NA,481,"mgdw/L",2,NA,19,NA,13.435,2,0.571,25.11,-9.854,13.137
"56",56,57,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Microcystis aerigunosa","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","24",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,1170,"mgdw/L","biomass","biom","SS",NA,60,NA,42.426,2,36,NA,20,NA,742,"mgdw/L",2,NA,3,NA,2.121,2,0.571,42.479,-5.757,5.143
"57",57,58,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Microcystis aerigunosa","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","10",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,767,"mgdw/L","biomass","biom","SS",NA,17,NA,12.021,2,36,NA,20,NA,406,"mgdw/L",2,NA,16,NA,11.314,2,0.571,16.508,-12.496,20.52
"58",58,59,"45","Goncalves et al",2016,"The effects of light and temperature on microalgal growth and nutrient removal: an experimental and mathematical approach","RSC ADVANCES",1,"3 different light:dark periods used(24h, 10h:14h, 14h:10h)",NA,"Table 2, supplementary data Fig 1",NA,"2015","Lab","culture",NA,NA,NA,"Microcystis aerigunosa","phytoplankton",11,"microcosm","flasks",0.5,NA,"no","temperature","reduced light","14",NA,NA,25,7,NA,NA,1453,17849,1453,17849,NA,4,180,NA,100,NA,991,"mgdw/L","biomass","biom","SS",NA,7,NA,4.95,2,36,NA,20,NA,484,"mgdw/L",2,NA,7,NA,4.95,2,0.571,7,-41.388,215.118
"59",59,60,"47","Laviale et al",2016,"The importance of being fast: comparative kinetics of vertical migration and non-photochemical quenching of benthic diatoms under light stress","MARINE BIOLOGY",1,NA,"temporal time scale of minutes",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"60",60,61,"51","Passow & Laws",2015,"Ocean acidification as one of multiple stressors: growth response of Thalassiosira weissflogii (diatom) under temperature and light stress","MARINE ECOLOGY PROGRESS SERIES",1,"combined stressors of CO² increase, suboptimal light + different temperatures",NA,"Table 2",NA,NA,"Lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",4,"microcosm","Fernbach flasks",1,NA,"no","nut","reduced light","14",NA,NA,20,8.3,NA,33,3.8,72,3.8,72,54,5,65,NA,100,NA,6,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.52,NA,0.3,3,35,NA,53.8,NA,2.1,"Chl a (pg/cell)",1,NA,0.2,NA,0.1,4,0.842,0.363,-9.039,6.42
"61",61,62,"51","Passow & Laws",2015,"Ocean acidification as one of multiple stressors: growth response of Thalassiosira weissflogii (diatom) under temperature and light stress","MARINE ECOLOGY PROGRESS SERIES",1,"combined stressors of CO² increase, suboptimal light + different temperatures",NA,"Table 2",NA,NA,"Lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",4,"microcosm","Fernbach flasks",1,NA,"no","nut_temp","reduced light","14",NA,NA,20,8.3,NA,33,3.8,72,3.8,72,54,5,65,NA,100,NA,596,"pgdw/cell","cellular content","phys","Q",NA,110.851,NA,64,3,35,NA,53.8,NA,375,"pgdw/cell",2,NA,40,NA,20,4,0.842,76.65,-2.428,1.004
"62",62,63,"51","Passow & Laws",2015,"Ocean acidification as one of multiple stressors: growth response of Thalassiosira weissflogii (diatom) under temperature and light stress","MARINE ECOLOGY PROGRESS SERIES",1,"combined stressors of CO² increase, suboptimal light + different temperatures",NA,"Table 2",NA,NA,"Lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",4,"microcosm","Fernbach flasks",1,NA,"no","nut_temp","reduced light","14",NA,NA,20,8.3,NA,33,3.8,72,3.8,72,54,5,65,NA,100,NA,0.84,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.02,3,35,NA,53.8,NA,0.68,"Growth rate (µ/d)",2,NA,0.04,NA,0.02,4,0.842,0.038,-3.551,1.484
"63",63,64,"62","Laviale et al",2015,"Response of intertidal benthic microalgal biofilms to a coupled light-temperature stress: evidence for latitudinal adaptation along the Atlantic coast of Southern Europe","ENVIRONMENTAL MICROBIOLOGY",1,NA,"Experiment duration only 3 h",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"64",64,65,"68","Walter et al",2015,"Interactive effects of temperature and light during deep convection: a case study on growth and condition of the diatom Thalassiosira weissflogii","ICES JOURNAL OF MARINE SCIENCE",1,"two different light scenarios, constant low light 20umol, 12:12h and pulsed high light 120umol, 2:22h.Same daily light dose","Pulsed  light for CTRL and constant light for TRT","Fig 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",6,"microcosm","covered glass beaker",1,NA,"no","temperature","reduced light","2",NA,NA,14.6,NA,NA,32,NA,NA,NA,NA,NA,0,120,NA,100,NA,0.23,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.011,NA,0.006,3,20,NA,16.7,NA,0.334,"Growth rate (µ/d)",2,NA,0.048,NA,0.028,3,0.8,0.035,2.389,1.142
"65",65,66,"68","Walter et al",2015,"Interactive effects of temperature and light during deep convection: a case study on growth and condition of the diatom Thalassiosira weissflogii","ICES JOURNAL OF MARINE SCIENCE",1,"two different light scenarios, constant low light 20umol, 12:12h and pulsed high light 120umol, 2:22h.Same daily light dose","Pulsed  light for CTRL and constant light for TRT","Fig 2a",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",6,"microcosm","covered glass beaker",1,NA,"no","temperature","reduced light","2",NA,NA,14.6,NA,NA,32,NA,NA,NA,NA,NA,0,120,NA,100,NA,3.619,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.776,NA,0.448,3,20,NA,16.7,NA,6.74,"Chl a (pg/cell)",1,NA,0.508,NA,0.293,3,0.8,0.656,3.807,1.874
"66",66,67,"74","Domingues et al",2015,"Are nutrients and light limiting summer phytoplankton in a temperate coastal lagoon?","AQUATIC ECOLOGY",1,"Mixed layer irradiance used as trt, high light irradiance as ctrl",NA,"Fig 7a","summer","2012","Field","coastal",37,-8,"Ria Formosa inner lagoon, Portugal","Diatoms","phytoplankton",1,"microcosm","Nalgene bottles",2,NA,"yes","nutrients","shading screen","Natural",500,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.551,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.364,NA,0.257,2,500,NA,50,NA,1.176,"Growth rate (µ/d)",2,NA,0.177,NA,0.125,2,0.571,0.286,1.248,1.195
"67",67,68,"74","Domingues et al",2015,"Are nutrients and light limiting summer phytoplankton in a temperate coastal lagoon?","AQUATIC ECOLOGY",1,"Mixed layer irradiance used as trt, high light irradiance as ctrl",NA,"Fig 7c","summer","2012","Field","coastal",37,-8,"Ria Formosa inner lagoon, Portugal","Cryptophytes","phytoplankton",1,"microcosm","Nalgene bottles",2,NA,"yes","nutrients","shading screen","Natural",500,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,1000,NA,100,NA,-1.63,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.461,NA,0.326,2,500,NA,50,NA,-0.283,"Growth rate (µ/d)",2,NA,0.8,NA,0.566,2,0.571,0.653,1.179,1.174
"68",68,69,"74","Domingues et al",2015,"Are nutrients and light limiting summer phytoplankton in a temperate coastal lagoon?","AQUATIC ECOLOGY",1,"Mixed layer irradiance used as trt, high light irradiance as ctrl",NA,"Fig 7e","summer","2012","Field","coastal",37,-8,"Ria Formosa inner lagoon, Portugal","Picophytoplankton","phytoplankton",1,"microcosm","Nalgene bottles",2,NA,"yes","nutrients","shading screen","Natural",500,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,1000,NA,100,NA,-0.589,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.216,NA,0.153,2,500,NA,50,NA,-0.989,"Growth rate (µ/d)",2,NA,0.102,NA,0.072,2,0.571,0.169,-1.353,1.229
"69",69,70,"74","Domingues et al",2015,"Are nutrients and light limiting summer phytoplankton in a temperate coastal lagoon?","AQUATIC ECOLOGY",1,"Mixed layer irradiance used as trt, high light irradiance as ctrl",NA,"Fig 7b","summer","2012","Field","coastal",37,-8,"Ria Formosa inner lagoon, Portugal","Dinoflagellates","phytoplankton",1,"microcosm","Nalgene bottles",2,NA,"yes","nutrients","shading screen","Natural",500,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,1000,NA,100,NA,1.217,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.442,NA,0.313,2,500,NA,50,NA,-0.376,"Growth rate (µ/d)",2,NA,0.476,NA,0.337,2,0.571,0.459,-1.982,1.491
"70",70,71,"74","Domingues et al",2015,"Are nutrients and light limiting summer phytoplankton in a temperate coastal lagoon?","AQUATIC ECOLOGY",1,"Mixed layer irradiance used as trt, high light irradiance as ctrl",NA,"Fig 7d","summer","2012","Field","coastal",37,-8,"Ria Formosa inner lagoon, Portugal","Nanoflagellates","phytoplankton",1,"microcosm","Nalgene bottles",2,NA,"yes","nutrients","shading screen","Natural",500,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,1000,NA,100,NA,-0.448,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.423,NA,0.299,2,500,NA,50,NA,0.417,"Growth rate (µ/d)",2,NA,0.082,NA,0.058,2,0.571,0.305,1.622,1.329
"71",71,72,"74","Domingues et al",2015,"Are nutrients and light limiting summer phytoplankton in a temperate coastal lagoon?","AQUATIC ECOLOGY",1,"Mixed layer irradiance used as trt, high light irradiance as ctrl",NA,"Fig 7f","summer","2012","Field","coastal",37,-8,"Ria Formosa inner lagoon, Portugal","Cyanobacteria","phytoplankton",1,"microcosm","Nalgene bottles",2,NA,"yes","nutrients","shading screen","Natural",500,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.556,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.559,NA,0.395,2,500,NA,50,NA,0.904,"Growth rate (µ/d)",2,NA,0.566,NA,0.4,2,0.571,0.563,0.354,1.016
"72",72,73,"75","Combe, C; Hartmann, P; Rabouille, S; Talec, A; Bernard, O; Sciandra, A",2015,"Long-Term Adaptive Response to High-Frequency Light Signals in the Unicellular Photosynthetic Eukaryote Dunaliella Salina","BIOTECHNOLOGY AND BIOENGINEERING",1,NA,"high frequency light signals used, no comparable continuous irradiance values available",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"73",73,74,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",1,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,420.843,"Chl a (µg/g)","cellular content","phys","Q",NA,11.252,NA,6.496,3,60,NA,6,NA,460.541,"Chl a (µg/g)",2,NA,31.704,NA,18.304,3,0.8,23.788,1.335,0.815
"74",74,81,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",1,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,420.843,"Chl a (µg/g)","cellular content","phys","Q",NA,11.252,NA,6.496,3,600,NA,60,NA,413.077,"Chl a (µg/g)",2,NA,10.225,NA,5.903,3,0.8,10.751,-0.578,0.694
"75",75,75,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",2,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,379.116,"Chl a (µg/g)","cellular content","phys","Q",NA,17.386,NA,10.038,3,60,NA,6,NA,487.334,"Chl a (µg/g)",2,NA,7.159,NA,4.133,3,0.8,13.295,6.512,4.2
"76",76,82,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",2,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,379.116,"Chl a (µg/g)","cellular content","phys","Q",NA,17.386,NA,10.038,3,600,NA,60,NA,415.327,"Chl a (µg/g)",2,NA,13.3,NA,7.679,3,0.8,15.478,1.872,0.959
"77",77,76,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",3,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,368.071,"Chl a (µg/g)","cellular content","phys","Q",NA,18.416,NA,10.632,3,60,NA,6,NA,511.059,"Chl a (µg/g)",2,NA,17.391,NA,10.041,3,0.8,17.911,6.387,4.066
"78",78,83,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",3,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,368.071,"Chl a (µg/g)","cellular content","phys","Q",NA,18.416,NA,10.632,3,600,NA,60,NA,366.441,"Chl a (µg/g)",2,NA,18.414,NA,10.631,3,0.8,18.415,-0.071,0.667
"79",79,77,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",4,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,332.48,"Chl a (µg/g)","cellular content","phys","Q",NA,14.327,NA,8.272,3,60,NA,6,NA,512.286,"Chl a (µg/g)",2,NA,16.371,NA,9.452,3,0.8,15.383,9.351,7.953
"80",80,84,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",4,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,332.48,"Chl a (µg/g)","cellular content","phys","Q",NA,14.327,NA,8.272,3,600,NA,60,NA,380.962,"Chl a (µg/g)",2,NA,14.325,NA,8.271,3,0.8,14.326,2.707,1.277
"81",81,78,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",5,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,293.821,"Chl a (µg/g)","cellular content","phys","Q",NA,10.227,NA,5.905,3,60,NA,6,NA,503.284,"Chl a (µg/g)",2,NA,31.707,NA,18.306,3,0.8,23.558,7.113,4.883
"82",82,85,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",5,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,293.821,"Chl a (µg/g)","cellular content","phys","Q",NA,10.227,NA,5.905,3,600,NA,60,NA,346.394,"Chl a (µg/g)",2,NA,18.413,NA,10.631,3,0.8,14.893,2.824,1.331
"83",83,79,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",6,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,267.435,"Chl a (µg/g)","cellular content","phys","Q",NA,20.457,NA,11.811,3,60,NA,6,NA,507.582,"Chl a (µg/g)",2,NA,22.502,NA,12.992,3,0.8,21.504,8.934,7.318
"84",84,86,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",6,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,267.435,"Chl a (µg/g)","cellular content","phys","Q",NA,20.457,NA,11.811,3,600,NA,60,NA,330.235,"Chl a (µg/g)",2,NA,31.706,NA,18.305,3,0.8,26.681,1.883,0.962
"85",85,80,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",7,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,233.89,"Chl a (µg/g)","cellular content","phys","Q",NA,23.529,NA,13.584,3,60,NA,6,NA,500.627,"Chl a (µg/g)",2,NA,31.707,NA,18.306,3,0.8,27.919,7.643,5.535
"86",86,87,"76","Torres, PB; Chow, F; Santos, DYAC",2015,"Growth and photosynthetic pigments of Gracilariopsis tenuifrons (Rhodophyta, Gracilariaceae) under high light in vitro culture","JOURNAL OF APPLIED PHYCOLOGY",1,"Apical tips (3cm) of Gracilaria female gametphytic phase, acclimated for 1 month at 60µmol, high light stress",NA,"Fig 4c,f,i",NA,NA,"Lab","culture",NA,NA,NA,"Gracilariopsis tenuiformis","macroalgae",7,"microcosm","Erlenmeyer flask",NA,NA,"no","none","reduced light","14",60,"PAR",25,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,233.89,"Chl a (µg/g)","cellular content","phys","Q",NA,23.529,NA,13.584,3,600,NA,60,NA,267.03,"Chl a (µg/g)",2,NA,12.275,NA,7.087,3,0.8,18.766,1.413,0.833
"87",87,88,"78","Spilling et al",2015,"Interaction Effects of Light, Temperature and Nutrient Limitations (N, P and Si) on Growth, Stoichiometry and Photosynthetic Parameters of the Cold-Water Diatom Chaetoceros wighamii","PLOS ONE",1,"Cold water diatom Chaetoceros wighamii cultured in 20,40,130,450umol photons at 3 different temperatures","No replicates","Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Chaetoceros wighamii","phytoplankton",3,"microcosm","Polycarbonate bottles",2,NA,"no","nut_temp","shading screen","16",NA,NA,11,NA,NA,6,NA,NA,NA,NA,NA,0,450,NA,NA,NA,0.75,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.01,NA,0.01,1,40,NA,8.9,NA,0.45,"Growth rate (µ/d)",2,NA,0.02,NA,0.02,1,4,NA,NA,NA
"88",88,89,"81","Hallenbeck, PC; Grogger, M; Mraz, M; Veverka, D",2015,"The use of Design of Experiments and Response Surface Methodology to optimize Biomass and lipid production by the oleaginous marine green alga, Nannochloropsis gaditana in response to light intensity, inoculum size and CO2","BIORESOURCE TECHNOLOGY",1,NA,"experiment unit volume only 50ml, Replicates? Duration?",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"89",89,90,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae",NA,"Table 1,Fig 3b",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,115.093,"Chl a (µg/g)","cellular content","phys","Q",NA,19.875,NA,11.475,3,212,NA,67.5,NA,112.41,"Chl a (µg/g)",2,NA,9.37,NA,5.41,3,0.8,15.538,-0.138,0.668
"90",90,91,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae",NA,"Table 1,Fig 3b",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,115.093,"Chl a (µg/g)","cellular content","phys","Q",NA,19.875,NA,11.475,3,103,NA,32.8,NA,112.193,"Chl a (µg/g)",2,NA,5.962,NA,3.442,3,0.8,14.673,-0.158,0.669
"91",91,92,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae",NA,"Table 1,Fig 3b",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,115.093,"Chl a (µg/g)","cellular content","phys","Q",NA,19.875,NA,11.475,3,44,NA,14,NA,137.498,"Chl a (µg/g)",2,NA,15.614,NA,9.015,3,0.8,17.872,1.003,0.75
"92",92,93,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae",NA,"Table 1,Fig 3b",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,115.093,"Chl a (µg/g)","cellular content","phys","Q",NA,19.875,NA,11.475,3,30,NA,9.6,NA,149.479,"Chl a (µg/g)",2,NA,20.443,NA,11.803,3,0.8,20.161,1.364,0.822
"93",93,94,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae",NA,"Table 1,Fig 3b",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,115.093,"Chl a (µg/g)","cellular content","phys","Q",NA,19.875,NA,11.475,3,21,NA,6.7,NA,198.995,"Chl a (µg/g)",2,NA,33.507,NA,19.345,3,0.8,27.547,2.437,1.161
"94",94,95,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae",NA,"Table 1,Fig 3b",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,115.093,"Chl a (µg/g)","cellular content","phys","Q",NA,19.875,NA,11.475,3,6,NA,1.9,NA,166.227,"Chl a (µg/g)",2,NA,9.086,NA,5.246,3,0.8,15.453,2.647,1.251
"95",95,96,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips",NA,"Table 1, Fig 4",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,1.677,"cm/d","growth rate","biom","dSS",NA,0.147,NA,0.085,3,212,NA,67.5,NA,3.19,"cm/d",2,NA,0.655,NA,0.378,3,0.8,0.475,2.551,1.209
"96",96,97,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips",NA,"Table 1, Fig 4",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,1.677,"cm/d","growth rate","biom","dSS",NA,0.147,NA,0.085,3,103,NA,32.8,NA,2.293,"cm/d",2,NA,0.284,NA,0.164,3,0.8,0.226,2.178,1.062
"97",97,98,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips",NA,"Table 1, Fig 4",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,1.677,"cm/d","growth rate","biom","dSS",NA,0.147,NA,0.085,3,44,NA,14,NA,2.443,"cm/d",2,NA,0.385,NA,0.222,3,0.8,0.291,2.105,1.036
"98",98,99,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips",NA,"Table 1, Fig 4",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,1.677,"cm/d","growth rate","biom","dSS",NA,0.147,NA,0.085,3,30,NA,9.6,NA,2.69,"cm/d",2,NA,0.669,NA,0.386,3,0.8,0.484,1.674,0.9
"99",99,100,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips",NA,"Table 1, Fig 4",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,1.677,"cm/d","growth rate","biom","dSS",NA,0.147,NA,0.085,3,21,NA,6.7,NA,2.194,"cm/d",2,NA,0.249,NA,0.144,3,0.8,0.205,2.02,1.007
"100",100,101,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips",NA,"Table 1, Fig 4",NA,NA,"Lab","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"mesocosm","Aquaria",100,NA,"unknown","none","reduced light","12",103,"PAR",19,NA,NA,37.5,NA,NA,NA,NA,NA,0,314,NA,100,NA,1.677,"cm/d","growth rate","biom","dSS",NA,0.147,NA,0.085,3,6,NA,1.9,NA,1,"cm/d",2,NA,0.147,NA,0.085,3,0.8,0.147,-3.679,1.794
"101",101,102,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macrolagae, (ctrl OUT, SHADED trt )",NA,"Fig 1, Fig 5b","fall",NA,"Field","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"field plot","no container",NA,4,"unknown","none","shading screen",NA,103,"PAR",19.8,NA,NA,37.5,NA,NA,NA,NA,NA,0,196,NA,100,NA,120.163,"Chl a (µg/g)","cellular content","phys","Q",NA,21.788,NA,10.894,4,21,NA,10.7,NA,143.089,"Chl a (µg/g)",2,NA,26.992,NA,13.496,4,0.87,24.528,0.813,0.541
"102",102,103,"83","Bernardeau-Esteller, J; Ruiz, JM; Tomas, F; Sandoval-Gil, JM; Marin-Guirao, L",2015,"Photoacclimation of Caulerpa cylindracea: Light as a limiting factor in the invasion, of native Mediterranean seagrass meadows","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae, apical tips (ctrl OUT, SHADED trt )",NA,"Fig 1, Fig 6","fall",NA,"Field","coastal",37.72,-0.71,"Isla Grosa, Spain","Caulerpa cylindracea","macroalgae",7,"field plot","no container",NA,4,"unknown","none","shading screen",NA,103,"PAR",19.8,NA,NA,37.5,NA,NA,NA,NA,NA,0,196,NA,100,NA,1.117,"cm/d","growth rate","biom","dSS",NA,0.244,NA,0.122,4,21,NA,10.7,NA,0.699,"cm/d",2,NA,0.232,NA,0.116,4,0.87,0.238,-1.527,0.646
"103",103,104,"84","Takache et al",2015,"Investigation of light/dark cycles effects on the photosynthetic growth of Chlamydomonas reinhardtii in conditions representative of photobioreactor cultivation","ALGAL RESEARCH-Biomass BIOFUELS AND BIOPRODUCTS",1,NA,"very short light:dark cycle durations 1-60s",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"104",104,105,"86","Edwards et al",2015,"Light and growth in marine phytoplankton: allometric, taxonomic, and environmental variation","LIMNOLOGY AND OCEANOGRAPHY",1,"very useful","Meta-analysis, with no actual experiment",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"105",105,108,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, summer",NA,"Fig 6j, 7r","summer","2003","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",36,"field plot","no container",NA,3,"unknown","none","shading screen",NA,203,"PAR",23.2,NA,NA,NA,NA,NA,NA,NA,NA,0,203,NA,100,NA,268.103,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,37.329,NA,21.552,3,8,NA,3.9,NA,26.724,"specific primary production (mg C /mg C/d)",1,NA,40.315,NA,23.276,3,0.8,38.851,-4.97,2.725
"106",106,109,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, summer",NA,"Fig 6j, 7r","summer","2003","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",36,"field plot","no container",NA,3,"unknown","none","shading screen",NA,203,"PAR",23.2,NA,NA,NA,NA,NA,NA,NA,NA,0,203,NA,100,NA,25.471,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,3.303,NA,1.907,3,8,NA,3.9,NA,4.869,"specific primary production (mg C /mg C/d)",1,NA,3.409,NA,1.968,3,0.8,3.356,-4.911,2.676
"107",107,106,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, spring",NA,"Fig 6i, 7q","spring","2003","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",41,"field plot","no container",NA,3,"unknown","none","shading screen",NA,310,"PAR",15.8,NA,NA,NA,NA,NA,NA,NA,NA,0,310,NA,100,15166.667,255.172,"total Biomass (above, belowground) (g dw / m²)","biomass","biom","SS",NA,114.974,NA,66.38,3,30,NA,9.7,14400,137.931,"total Biomass (above, belowground) (g dw / m²)",2,360.555,35.836,NA,20.69,3,0.8,85.156,-1.101,0.768
"108",108,107,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, spring",NA,"Fig 6i, 7q","spring","2003","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",41,"field plot","no container",NA,3,"unknown","none","shading screen",NA,310,"PAR",15.8,NA,NA,NA,NA,NA,NA,NA,NA,0,310,NA,100,NA,30.73,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,4.581,NA,2.645,3,30,NA,9.7,NA,20.152,"specific primary production (mg C /mg C/d)",1,NA,7.775,NA,4.489,3,0.8,6.381,-1.326,0.813
"109",109,110,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, fall",NA,"Fig 6k, 7s","fall","2003","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",43,"field plot","no container",NA,3,"unknown","none","shading screen",NA,168,"PAR",16,NA,NA,NA,NA,NA,NA,NA,NA,0,168,NA,100,NA,188.793,"total Biomass (above, belowground) (g dw / m²)","biomass","biom","SS",NA,64.205,NA,37.069,3,17,NA,10.1,NA,18.966,"total Biomass (above, belowground) (g dw / m²)",2,NA,68.684,NA,39.655,3,0.8,66.483,-2.044,1.015
"110",110,111,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, fall",NA,"Fig 6k, 7s","fall","2003","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",43,"field plot","no container",NA,3,"unknown","none","shading screen",NA,168,"PAR",16,NA,NA,NA,NA,NA,NA,NA,NA,0,168,NA,100,NA,23.895,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,3.301,NA,1.906,3,17,NA,10.1,NA,4.83,"specific primary production (mg C /mg C/d)",1,NA,3.088,NA,1.783,3,0.8,3.197,-4.771,2.564
"111",111,112,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, winter",NA,"Fig 6l, 7t","winter","2004","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",44,"field plot","no container",NA,3,"unknown","none","shading screen",NA,296,"PAR",8.2,NA,NA,NA,NA,NA,NA,NA,NA,0,296,NA,100,NA,246.552,"total Biomass (above, belowground) (g dw / m²)","biomass","biom","SS",NA,38.822,NA,22.414,3,51,NA,17.2,NA,33.621,"total Biomass (above, belowground) (g dw / m²)",2,NA,34.341,NA,19.827,3,0.8,36.65,-4.648,2.467
"112",112,113,"87","Kim, YK; Kim, SH; Lee, KS",2015,"Seasonal Growth Responses of the Seagrass Zostera marina under Severely Diminished Light Conditions","ESTUARIES AND COASTS",1,"seagrass, four different experimental periods, winter",NA,"Fig 6l, 7t","winter","2004","Field","coastal",34.8,128.58,"Koje Bay, South Korea","Zostera marina","seagrass",44,"field plot","no container",NA,3,"unknown","none","shading screen",NA,296,"PAR",8.2,NA,NA,NA,NA,NA,NA,NA,NA,0,296,NA,100,NA,26.563,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,8.096,NA,4.674,3,51,NA,17.2,NA,14.325,"specific primary production (mg C /mg C/d)",1,NA,2.662,NA,1.537,3,0.8,6.026,-1.625,0.887
"113",113,114,"91","Juneau et al",2015,"Combined effect of high light and high salinity on the regulation of photosynthesis in three diatom species belonging to the main growth forms of intertidal flat inhabiting microphytobenthos","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"MPB","Experiment time only 1-3h",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"114",114,115,"92","Valenti et al",2015,"How Diffusivity, Thermocline and Incident Light Intensity Modulate the Dynamics of Deep Chlorophyll Maximum in Tyrrhenian Sea","PLOS ONE",1,NA,"No experiment, just a model",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"115",115,116,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 1","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,1.655,"Ramet growth rate (mgdw / d)","growth rate","biom","dSS",NA,0.36,NA,0.208,3,181,NA,22.1,NA,1.013,"Ramet growth rate (mgdw / d)",2,NA,0.43,NA,0.248,3,0.8,0.396,-1.296,0.807
"116",116,117,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 2","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,2.321,"Ramet growth rate (mgdw / d)","growth rate","biom","dSS",NA,0.677,NA,0.391,3,181,NA,22.1,NA,1.048,"Ramet growth rate (mgdw / d)",2,NA,0.445,NA,0.257,3,0.8,0.573,-1.777,0.93
"117",117,118,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 3","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,1.608,"Ramet growth rate (mgdw / d)","growth rate","biom","dSS",NA,0.442,NA,0.255,3,181,NA,22.1,NA,1.224,"Ramet growth rate (mgdw / d)",2,NA,0.611,NA,0.353,3,0.8,0.533,-0.576,0.694
"118",118,119,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 4","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,1.999,"Ramet growth rate (mgdw / d)","growth rate","biom","dSS",NA,0.215,NA,0.124,3,181,NA,22.1,NA,1.444,"Ramet growth rate (mgdw / d)",2,NA,0.468,NA,0.27,3,0.8,0.364,-1.22,0.791
"119",119,120,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 1","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,0.14,"Biomass (g / Ramet)","biomass","biom","SS",NA,0.05,NA,0.029,3,181,NA,22.1,NA,0.095,"Biomass (g / Ramet)",2,NA,0.014,NA,0.008,3,0.8,0.037,-0.977,0.746
"120",120,121,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 2","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,0.176,"Biomass (g / Ramet)","biomass","biom","SS",NA,0.048,NA,0.028,3,181,NA,22.1,NA,0.094,"Biomass (g / Ramet)",2,NA,0.016,NA,0.009,3,0.8,0.036,-1.821,0.943
"121",121,122,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 3","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,0.168,"Biomass (g / Ramet)","biomass","biom","SS",NA,0.036,NA,0.021,3,181,NA,22.1,NA,0.128,"Biomass (g / Ramet)",2,NA,0.031,NA,0.018,3,0.8,0.034,-0.945,0.741
"122",122,123,"93","Salo, T; Reusch, TBH; Bostrom, C",2015,"Genotype-specific responses to light stress in eelgrass Zostera marina, a marine foundation plant","MARINE ECOLOGY PROGRESS SERIES",1,"eelgrass. ambient light values given for midday irradiance only, from 10.00-14.00, Biomass and growth --> 4 different genotypes used",NA,"Fig 1, 2ac","summer","2011","Field","coastal",60.03,22.33,"Sandön, Finland","Zostera marina, genotype 4","seagrass",28,"field plot","no container",NA,7,"unknown","none","shading screen",NA,818,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,818,NA,100,NA,0.176,"Biomass (g / Ramet)","biomass","biom","SS",NA,0.017,NA,0.01,3,181,NA,22.1,NA,0.126,"Biomass (g / Ramet)",2,NA,0.026,NA,0.015,3,0.8,0.022,-1.812,0.94
"123",123,124,"94","Kim  et al",2015,"Growth and pigment content of Gracilaria tikvahiae McLachlan under fluorescent and LED lighting","AQUACULTURE",1,"red algae","only a comparison between LED and fluoroescent lights, no intensity treatment",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"124",124,125,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4a","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia eptihemoides","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,719200,"cell /mL","abundance","biom","SS",NA,116895,NA,58448,4,40,NA,33.3,NA,791200,"cell /mL",2,NA,76114,NA,38057,4,0.87,98635.141,0.635,0.525
"125",125,126,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4a","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia eptihemoides","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,1.38,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.72,NA,0.36,4,40,NA,33.3,NA,1.73,"Growth rate (µ/d)",2,NA,0.38,NA,0.19,4,0.87,0.576,0.529,0.517
"126",126,127,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4a","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia eptihemoides","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,719200,"cell /mL","abundance","biom","SS",NA,116895,NA,58448,4,80,NA,66.7,NA,692800,"cell /mL",2,NA,107704,NA,53852,4,0.87,112393.489,-0.204,0.503
"127",127,128,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4a","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia eptihemoides","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,1.38,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.72,NA,0.36,4,80,NA,66.7,NA,1.8,"Growth rate (µ/d)",2,NA,0.56,NA,0.28,4,0.87,0.645,0.566,0.52
"128",128,129,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4b","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia sp.","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,709440,"cell /mL","abundance","biom","SS",NA,128200,NA,64100,4,40,NA,33.3,NA,667200,"cell /mL",2,NA,38467,NA,19234,4,0.87,94643.938,-0.388,0.509
"129",129,130,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4b","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia sp.","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,0.96,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.39,NA,0.195,4,40,NA,33.3,NA,0.77,"Growth rate (µ/d)",2,NA,0.6,NA,0.3,4,0.87,0.506,-0.327,0.507
"130",130,131,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4b","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia sp.","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,709440,"cell /mL","abundance","biom","SS",NA,128200,NA,64100,4,80,NA,66.7,NA,643800,"cell /mL",2,NA,128640,NA,64320,4,0.87,128420.188,-0.444,0.512
"131",131,132,"98","Ramirez, EE; Gonzalez, MA; Cifuentes, AS; Inostroza, I; Urrutia, RE",2015,"Culture and growth of two benthic diatoms species isolated from the Salar del Huasco (North of Chile, 20 degrees S) at different conditions of temperature, light and nutrient","GAYANA BOTANICA",1,"WebPlot Digitizer couldn't handle scale from 100 to 1000000, so only data for the last day of exp, given in results","Saline lake","Fig 4b","spring","2012","Lab",NA,-20.29,-68.87,"Salar de Huasco, Chile","Nitzschia sp.","phytobenthos",18,"microcosm","Erlenmeyer flask",0.25,NA,"no","nut_temp","reduced light","18",NA,NA,20,8,52000,38.4,36.2,882,NA,NA,106,3,120,NA,100,NA,0.96,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.39,NA,0.195,4,80,NA,66.7,NA,0.87,"Growth rate (µ/d)",2,NA,0.38,NA,0.19,4,0.87,0.385,-0.203,0.503
"132",132,133,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,0.31,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.11,NA,0.064,3,250,NA,55.6,NA,0.49,"Growth rate (µ/d)",2,NA,0.13,NA,0.075,3,0.8,0.12,1.196,0.786
"133",133,134,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,0.31,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.11,NA,0.064,3,130,NA,28.9,NA,1.24,"Growth rate (µ/d)",2,NA,0.23,NA,0.133,3,0.8,0.18,4.127,2.086
"134",134,135,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,0.31,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.11,NA,0.064,3,88,NA,19.6,NA,0.4,"Growth rate (µ/d)",2,NA,0.27,NA,0.156,3,0.8,0.206,0.349,0.677
"135",135,136,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,1072880,"cell /mL","abundance","biom","SS",NA,166228,NA,95972,3,250,NA,55.6,NA,715593,"cell /mL",2,NA,122325,NA,70624,3,0.8,145936.893,-1.959,0.986
"136",136,137,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,715593,"cell /mL","abundance","biom","SS",NA,166228,NA,95972,3,130,NA,28.9,NA,738348,"cell /mL",2,NA,99598,NA,57503,3,0.8,137024.65,0.133,0.668
"137",137,138,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,738348,"cell /mL","abundance","biom","SS",NA,166228,NA,95972,3,88,NA,19.6,NA,678394,"cell /mL",2,NA,336142,NA,194072,3,0.8,265163.338,-0.181,0.669
"138",138,139,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Fig 3",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,0.024,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.004,NA,0.002,3,250,NA,55.6,NA,0.0256,"Chl a (pg/cell)",1,NA,0.008,NA,0.005,3,0.8,0.006,0.22,0.671
"139",139,140,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Fig 3",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,0.024,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.004,NA,0.002,3,130,NA,28.9,NA,0.0622,"Chl a (pg/cell)",1,NA,0.01,NA,0.006,3,0.8,0.007,4.108,2.073
"140",140,141,"103","Chandrasekaran, R; Barra, L; Carillo, S; Caruso, T; Corsaro, MM; Dal Piaz, F; Graziani, G; Corato, F; Pepe, D; Manfredonia, A; Orefice, I; Ruban, AV; Brunet, C",2014,"Light modulation of Biomass and macromolecular composition of the diatom Skeletonema marinoi, pre-acclimated for 2 weeks prior the experiment","JOURNAL OF BIOTECHNOLOGY",1,"sinusoidal blue fluence rates, sampling during exp growth phase, pre-acclimated for 2 weeks prior the experiment",NA,"Fig 3",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","glass flask",4.5,NA,"unknown","quality","reduced light","12",NA,"460",20,NA,NA,NA,36.2,882,36.2,882,106,5,450,NA,100,NA,0.024,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.004,NA,0.002,3,88,NA,19.6,NA,0.0616,"Chl a (pg/cell)",1,NA,0.017,NA,0.01,3,0.8,0.012,2.455,1.169
"141",141,142,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1a",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Phaeocystis antarctica","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.142,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.074,NA,0.043,3,50,NA,33.3,NA,0.262,"Growth rate (µ/d)",2,NA,0.31,NA,0.179,3,0.8,0.225,0.426,0.682
"142",142,143,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1a",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Phaeocystis antarctica","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.142,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.074,NA,0.043,3,100,NA,66.7,NA,0.295,"Growth rate (µ/d)",2,NA,0.32,NA,0.185,3,0.8,0.232,0.527,0.69
"143",143,144,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1b",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Fragilariopsis cylindrus","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.249,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.071,NA,0.041,3,50,NA,33.3,NA,0.171,"Growth rate (µ/d)",2,NA,0.011,NA,0.006,3,0.8,0.051,-1.228,0.792
"144",144,145,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1b",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Fragilariopsis cylindrus","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.249,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.071,NA,0.041,3,100,NA,66.7,NA,0.268,"Growth rate (µ/d)",2,NA,0.024,NA,0.014,3,0.8,0.053,0.287,0.674
"145",145,146,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1c",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Phaeocystis antarctica","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.083,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.008,NA,0.005,3,50,NA,33.3,NA,0.148,"Chl a (pg/cell)",1,NA,0.025,NA,0.014,3,0.8,0.019,2.802,1.321
"146",146,147,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1c",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Phaeocystis antarctica","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.083,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.008,NA,0.005,3,100,NA,66.7,NA,0.251,"Chl a (pg/cell)",1,NA,0.02,NA,0.012,3,0.8,0.015,8.824,7.155
"147",147,148,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1d",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Fragilariopsis cylindrus","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.04,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.007,NA,0.004,3,50,NA,33.3,NA,0.091,"Chl a (pg/cell)",1,NA,0.014,NA,0.008,3,0.8,0.011,3.686,1.799
"148",148,149,"111","Xu, K; Fu, FX; Hutchins, DA",2014,"Comparative responses of two dominant Antarctic phytoplankton taxa to interactions between ocean acidification, warming, irradiance, and iron availability","LIMNOLOGY AND OCEANOGRAPHY",1,"Grown at 3 different temperatures, 2,4,6 'C. Light CTRL and TRT have different temperatures.","Different temp and CO2 conditions for CTRL and TRT","Fig 1d",NA,NA,"Lab","culture",NA,NA,"Ross Sea, Antarctica","Fragilariopsis cylindrus","phytoplankton",8,"microcosm","incubation bottle",NA,NA,"no","nut_temp","reduced light","12",NA,NA,2,7.8,NA,NA,1.5,23.6,1.5,23.6,66.3,5,150,NA,100,NA,0.04,"Chl a (pg/cell)","cellular content","phys","Q",NA,0.007,NA,0.004,3,100,NA,66.7,NA,0.037,"Chl a (pg/cell)",1,NA,0.004,NA,0.002,3,0.8,0.006,-0.421,0.681
"149",149,150,"114","Gorai, T; Katayama, T; Obata, M; Murata, A; Taguchi, S",2014,"Low blue light enhances growth rate, light absorption, and photosynthetic characteristics of four marine phytoplankton species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,NA,"Only a comparison between white light and blue light at same irradiance levels, no light intensity treatment",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"150",150,151,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 4,5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,710.319,682.611,"shoots/m2","abundance","biom","SS",NA,135.322,NA,78.128,3,44.2,NA,55.4,NA,601.162,"shoots/m2",2,NA,105.529,NA,60.927,3,0.8,121.343,-0.537,0.691
"151",151,153,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,53.017,"Above ground Biomass (gdw/m2)","biomass","biom","SS",NA,8.586,NA,4.957,3,44.2,NA,55.4,NA,51.293,"Above ground Biomass (gdw/m2)",2,NA,3.733,NA,2.155,3,0.8,6.62,-0.208,0.67
"152",152,154,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 6","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,2.173,"leaf area index (m² leaf/m² bottom)","biomass","biom","SS",NA,0.572,NA,0.33,3,44.2,NA,55.4,NA,2.135,"leaf area index (m² leaf/m² bottom)",2,NA,0.187,NA,0.108,3,0.8,0.425,-0.071,0.667
"153",153,155,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 6","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,2.479,"leaf width (mm)","biomass","biom","SS",NA,0.149,NA,0.086,3,44.2,NA,55.4,NA,2.541,"leaf width (mm)",2,NA,0.095,NA,0.055,3,0.8,0.125,0.397,0.68
"154",154,156,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 7","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,0.641,"Effective quantum yield","quantum yield","phys","dQ",NA,0.052,NA,0.03,3,44.2,NA,55.4,NA,0.696,"Effective quantum yield",1,NA,0.048,NA,0.028,3,0.8,0.05,0.875,0.731
"155",155,157,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 7","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,9.965,"relat electron transp rate (µmol e m²-s)","quantum yield","phys","dQ",NA,6.997,NA,4.04,3,44.2,NA,55.4,NA,6.57,"relat electron transp rate (µmol e m²-s)",1,NA,1.386,NA,0.8,3,0.8,5.044,-0.538,0.691
"156",156,158,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 4,5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,682.611,"shoots/m2","abundance","biom","SS",NA,135.322,NA,78.128,3,12,NA,15,NA,552.424,"shoots/m2",2,NA,115.824,NA,66.871,3,0.8,125.951,-0.827,0.724
"157",157,160,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,53.017,"Above ground Biomass (gdw/m2)","biomass","biom","SS",NA,8.586,NA,4.957,3,12,NA,15,NA,34.591,"Above ground Biomass (gdw/m2)",2,NA,3.546,NA,2.047,3,0.8,6.568,-2.244,1.086
"158",158,161,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 6","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,2.173,"leaf area index (m² leaf/m² bottom)","biomass","biom","SS",NA,0.572,NA,0.33,3,12,NA,15,NA,1.717,"leaf area index (m² leaf/m² bottom)",2,NA,0.208,NA,0.12,3,0.8,0.43,-0.848,0.727
"159",159,162,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 6","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,2.479,"leaf width (mm)","biomass","biom","SS",NA,0.149,NA,0.086,3,12,NA,15,NA,2.386,"leaf width (mm)",2,NA,0.052,NA,0.03,3,0.8,0.112,-0.667,0.704
"160",160,163,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 7","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,0.641,"Effective quantum yield","quantum yield","phys","dQ",NA,0.052,NA,0.03,3,12,NA,15,NA,0.737,"Effective quantum yield",1,NA,0.028,NA,0.016,3,0.8,0.042,1.844,0.95
"161",161,164,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 7","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,9.965,"relat electron transp rate (µmol e m²-s)","quantum yield","phys","dQ",NA,6.997,NA,4.04,3,12,NA,15,NA,1.786,"relat electron transp rate (µmol e m²-s)",1,NA,1.316,NA,0.76,3,0.8,5.035,-1.3,0.807
"162",162,165,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 4,5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,682.611,"shoots/m2","abundance","biom","SS",NA,135.322,NA,78.128,3,2.5,NA,3.1,NA,421.81,"shoots/m2",2,NA,365.341,NA,210.93,3,0.8,275.487,-0.757,0.714
"163",163,167,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,53.017,"Above ground Biomass (gdw/m2)","biomass","biom","SS",NA,8.586,NA,4.957,3,2.5,NA,3.1,NA,29.203,"Above ground Biomass (gdw/m2)",2,NA,9.145,NA,5.28,3,0.8,8.87,-2.148,1.051
"164",164,168,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 6","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,2.173,"leaf area index (m² leaf/m² bottom)","biomass","biom","SS",NA,0.572,NA,0.33,3,2.5,NA,3.1,NA,1.432,"leaf area index (m² leaf/m² bottom)",2,NA,0.438,NA,0.253,3,0.8,0.509,-1.164,0.78
"165",165,169,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 6","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,2.479,"leaf width (mm)","biomass","biom","SS",NA,0.149,NA,0.086,3,2.5,NA,3.1,NA,2.385,"leaf width (mm)",2,NA,0.109,NA,0.063,3,0.8,0.131,-0.576,0.694
"166",166,170,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 7","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,0.641,"Effective quantum yield","quantum yield","phys","dQ",NA,0.052,NA,0.03,3,2.5,NA,3.1,NA,0.788,"Effective quantum yield",1,NA,0.029,NA,0.017,3,0.8,0.042,2.785,1.313
"167",167,171,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 7","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",67,"field plot","no container",NA,3,"yes","none","shading screen","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,9.965,"relat electron transp rate (µmol e m²-s)","quantum yield","phys","dQ",NA,6.997,NA,4.04,3,2.5,NA,3.1,NA,0.361,"relat electron transp rate (µmol e m²-s)",1,NA,0.348,NA,0.201,3,0.8,4.954,-1.551,0.867
"168",168,152,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 4,5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",93,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,625.008,"shoots/m2","abundance","biom","SS",NA,123.707,NA,71.422,3,44.2,NA,55.4,NA,590.481,"shoots/m2",2,NA,101.022,NA,58.325,3,0.8,112.935,-0.245,0.672
"169",169,159,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 4,5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",93,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,625.008,"shoots/m2","abundance","biom","SS",NA,123.707,NA,71.422,3,44.2,NA,55.4,NA,485.712,"shoots/m2",2,NA,80.405,NA,46.422,3,0.8,104.327,-1.068,0.762
"170",170,166,"115","Skinner, MA; Courtenay, SC; McKindsey, CW; Carver, CE; Mallet, AL",2014,"Experimental determination of the effects of light limitation from suspended bag oyster (Crassostrea virginica) aquaculture on the structure and photosynthesis of eelgrass (Zostera marina)","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"3 different shading treatments on eelgrass",NA,"Fig 4,5","fall","2009","Field","coastal",47.43,-64.46,"St. Simon Bay, Canada","Zostera marina","seagrass",93,"field plot","no container",NA,3,"yes","none","Crassostrea virginica oysters glued to lines","Natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,79.8,NA,100,NA,625.008,"shoots/m2","abundance","biom","SS",NA,123.707,NA,71.422,3,44.2,NA,55.4,NA,327.379,"shoots/m2",2,NA,131.965,NA,76.19,3,0.8,127.902,-1.862,0.955
"171",171,172,"137","Tamburic, B; Guruprasad, S; Radford, DT; Szabo, M; Lilley, RM; Larkum, AWD; Franklin, JB; Kramer, DM; Blackburn, SI; Raven, JA; Schliep, M; Ralph, PJ",2014,"The Effect of Diel Temperature and Light Cycles on the Growth of Nannochloropsis oculata in a Photobioreactor Matrix","PLOS ONE",1,NA,"Non-extractable data",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"172",172,173,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","No replicates","Fig 3I","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,1097.48,"cell /mL","abundance","biom","SS",NA,192.97,NA,192.97,1,232,NA,43,NA,406.271,"cell /mL",2,NA,96.566,NA,96.566,1,4,NA,NA,NA
"173",173,176,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","weird log values","Fig 3J","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,80257.862,"cell /mL","abundance","biom","SS",NA,25721.537,NA,14850.336,3,232,NA,43,NA,89054.16,"cell /mL",2,NA,28540.629,NA,16477.94,3,0.8,27167.673,0.259,0.672
"174",174,179,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water",NA,"Fig 3G","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total phytoplankton","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,1.27,"Chl a (µg/L)","biomass","biom","SS",NA,0.119,NA,0.069,3,232,NA,43,NA,1.714,"Chl a (µg/L)",2,NA,0.497,NA,0.287,3,0.8,0.361,0.983,0.747
"175",175,182,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","percentages","Fig 3H","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton >20 µm","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,0.688,"Chl a (µg/L)","biomass","biom","SS",NA,0.407,NA,0.235,3,232,NA,43,NA,0.677,"Chl a (µg/L)",2,NA,1.052,NA,0.607,3,0.8,0.797,-0.012,0.667
"176",176,174,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","No replicates","Fig 3I","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,1385.47,"cell /mL","abundance","biom","SS",NA,298.23,NA,298.23,1,232,NA,43,NA,1186.304,"cell /mL",2,NA,219.294,NA,219.294,1,4,NA,NA,NA
"177",177,177,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","weird log values","Fig 3J","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,8275.048,"cell /mL","abundance","biom","SS",NA,1234.009,NA,712.455,3,232,NA,43,NA,8751.672,"cell /mL",2,NA,4528.137,NA,2614.321,3,0.8,3318.644,0.115,0.668
"178",178,180,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water",NA,"Fig 3G","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total phytoplankton","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,2.54,"Chl a (µg/L)","biomass","biom","SS",NA,0.239,NA,0.138,3,232,NA,43,NA,1.968,"Chl a (µg/L)",2,NA,0.369,NA,0.213,3,0.8,0.311,-1.472,0.847
"179",179,183,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","percentages","Fig 3H","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton >20 µm","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,2.54,"Chl a (µg/L)","biomass","biom","SS",NA,3.174,NA,1.832,3,232,NA,43,NA,1.44,"Chl a (µg/L)",2,NA,1.744,NA,1.007,3,0.8,2.561,-0.344,0.677
"180",180,175,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","No replicates","Fig 3I","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,1085.79,"cell /mL","abundance","biom","SS",NA,236.98,NA,236.98,1,232,NA,43,NA,501.337,"cell /mL",2,NA,70.174,NA,70.174,1,4,NA,NA,NA
"181",181,178,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","weird log values","Fig 3J","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,15047.994,"cell /mL","abundance","biom","SS",NA,3929.328,NA,2268.599,3,232,NA,43,NA,10498.629,"cell /mL",2,NA,10537.57,NA,6083.869,3,0.8,7952.358,-0.458,0.684
"182",182,181,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water",NA,"Fig 3G","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total phytoplankton","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,3.746,"Chl a (µg/L)","biomass","biom","SS",NA,0.675,NA,0.39,3,232,NA,43,NA,3.651,"Chl a (µg/L)",2,NA,0.328,NA,0.189,3,0.8,0.531,-0.143,0.668
"183",183,184,"139","Neale, PJ; Sobrino, C; Segovia, M; Mercado, JM; Leon, P; Cortes, MD; Tuite, P; Picazo, A; Salles, S; Cabrerizo, MJ; Prasil, O; Montecino, V; Reul, A; Fuentes-Lema, A",2014,"Effect of CO2, nutrients and light on coastal plankton. I. Abiotic conditions and biological responses","AQUATIC BIOLOGY",1,"sampled on days 2,4,6. High irradiance stress at time of sampling source water","percentages","Fig 3H","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton >20 µm","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,1.853,"Chl a (µg/L)","biomass","biom","SS",NA,1.273,NA,0.735,3,232,NA,43,NA,2.633,"Chl a (µg/L)",2,NA,3.104,NA,1.792,3,0.8,2.372,0.263,0.672
"184",184,185,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2a","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Phytoplankton","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,9.663,"µg POC/L/h","area-specific production","biom","dSS",NA,2.339,NA,1.35,3,232,NA,43,NA,9.033,"µg POC/L/h",1,NA,1.979,NA,1.143,3,0.8,2.166,-0.233,0.671
"185",185,188,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2b","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Phytoplankton","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,7.467,"µg POC/mg/Chl a/h","mass-specific production","phys","dQ",NA,0.382,NA,0.221,3,232,NA,43,NA,4.09,"µg POC/mg/Chl a/h",1,NA,0.044,NA,0.025,3,0.8,0.272,-9.936,8.894
"186",186,191,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2c","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton >20 µm","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,5.549,"µg POC/µg/Chl a/h","mass-specific production","phys","dQ",NA,1.097,NA,0.633,3,232,NA,43,NA,5.427,"µg POC/µg/Chl a/h",1,NA,0.975,NA,0.563,3,0.8,1.038,-0.094,0.667
"187",187,194,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2d","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton <20 µm","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,9.48,"µg POC/µg/Chl a/h","mass-specific production","phys","dQ",NA,1.34,NA,0.774,3,232,NA,43,NA,3.839,"µg POC/µg/Chl a/h",1,NA,0.367,NA,0.212,3,0.8,0.982,-4.594,2.425
"188",188,186,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2a","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Phytoplankton","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,20.009,"µg POC/L/h","area-specific production","biom","dSS",NA,1.844,NA,1.065,3,232,NA,43,NA,11.642,"µg POC/L/h",1,NA,1.529,NA,0.883,3,0.8,1.694,-3.952,1.968
"189",189,189,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,"STD not available for HL Ctrl, day 4 Fig 2b","STD not available for HL Ctrl, day 4 Fig 2b","Fig 2b","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Phytoplankton","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,NA,"µg POC/mg/Chl a/h","mass-specific production","phys","dQ",NA,NA,NA,NA,3,232,NA,43,NA,6.426,"µg POC/mg/Chl a/h",1,NA,0.696,NA,0.402,3,0.8,NA,NA,NA
"190",190,192,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2c","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton >20 µm","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,6.829,"µg POC/µg/Chl a/h","mass-specific production","phys","dQ",NA,1.128,NA,0.651,3,232,NA,43,NA,6.22,"µg POC/µg/Chl a/h",1,NA,0.914,NA,0.528,3,0.8,1.027,-0.475,0.685
"191",191,195,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,"STD not available for HL Ctrl, day 4 Fig 2d","STD not available for HL Ctrl, day 4 Fig 2d","Fig 2d","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton <20 µm","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,NA,"µg POC/µg/Chl a/h","mass-specific production","phys","dQ",NA,NA,NA,NA,3,232,NA,43,NA,7.249,"µg POC/µg/Chl a/h",1,NA,0.427,NA,0.247,3,0.8,NA,NA,NA
"192",192,187,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2a","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Phytoplankton","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,17.13,"µg POC/L/h","area-specific production","biom","dSS",NA,5.488,NA,3.168,3,232,NA,43,NA,18.21,"µg POC/L/h",1,NA,4.588,NA,2.649,3,0.8,5.058,0.171,0.669
"193",193,190,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2b","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Phytoplankton","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,6.207,"µg POC/mg/Chl a/h","mass-specific production","phys","dQ",NA,2.606,NA,1.505,3,232,NA,43,NA,5.302,"µg POC/mg/Chl a/h",1,NA,2.112,NA,1.219,3,0.8,2.372,-0.305,0.674
"194",194,193,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2c","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton >20 µm","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,5.488,"µg POC/µg/Chl a/h","mass-specific production","phys","dQ",NA,0.61,NA,0.352,3,232,NA,43,NA,3.415,"µg POC/µg/Chl a/h",1,NA,1.89,NA,1.091,3,0.8,1.404,-1.181,0.783
"195",195,196,"140","Mercado, JM; Sobrino, C; Neale, PJ; Segovia, M; Reul, A; Amorim, AL; Carrillo, P; Claquin, P; Cabrerizo, MJ; Leon, P; Lorenzo, MR; Medina-Sanchez, JM; Montecino, V; Napoleon, C; Prasil, O; Putzeys, S; Salles, S; Yebra, L",2014,"Effect of CO2, nutrients and light on coastal plankton. II. Metabolic rates","AQUATIC BIOLOGY",1,NA,NA,"Fig 2d","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Phytoplankton <20 µm","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,6.93,"µg POC/µg/Chl a/h","mass-specific production","phys","dQ",NA,4.199,NA,2.424,3,232,NA,43,NA,6.948,"µg POC/µg/Chl a/h",1,NA,4.26,NA,2.46,3,0.8,4.23,0.003,0.667
"196",196,200,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Green algae","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,0,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.34,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"197",197,205,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,0.66,0.455,"Chl a (µg/L)","biomass","biom","SS",0.226,0.065,0.13,0.038,3,232,NA,43,NA,0.451,"Chl a (µg/L)",2,NA,0.123,NA,0.071,3,0.8,0.098,-0.033,0.667
"198",198,210,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae 2-20um","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,0.018,0.277,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.031,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"199",199,215,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms 2-20um","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,0.184,0.893,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.96,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"200",200,220,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae >20um","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,0.002,0.296,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.327,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"201",201,225,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms >20um","phytoplankton",2,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,0.24,NA,"Chl a (µg/L)","biomass","biom","SS",0.12,NA,0.069,NA,3,232,NA,43,NA,0.05,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"202",202,201,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Green algae","phytoplankton",3,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.642,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"203",203,206,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",3,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.34,"Chl a (µg/L)","biomass","biom","SS",NA,0.109,NA,0.063,3,232,NA,43,NA,0.292,"Chl a (µg/L)",2,NA,0.183,NA,0.106,3,0.8,0.151,-0.255,0.672
"204",204,211,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae 2-20um","phytoplankton",3,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,0.805,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.171,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"205",205,216,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms 2-20um","phytoplankton",3,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,1.538,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,1.206,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"206",206,221,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae >20um","phytoplankton",3,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.243,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.458,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"207",207,226,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms >20um","phytoplankton",3,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,0.647,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.391,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"208",208,197,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Diatoms","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,1.054,3.292,"Chl a (µg/L)","biomass","biom","SS",0.135,1.312,0.078,0.757,3,232,NA,43,NA,2.447,"Chl a (µg/L)",2,NA,0.443,NA,0.256,3,0.8,0.979,-0.69,0.706
"209",209,202,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Green algae","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,0.43,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"210",210,207,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.068,"Chl a (µg/L)","biomass","biom","SS",NA,0.036,NA,0.021,3,232,NA,43,NA,0.139,"Chl a (µg/L)",2,NA,0.168,NA,0.097,3,0.8,0.121,0.468,0.685
"211",211,212,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae 2-20um","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.11,"Chl a (µg/L)","biomass","biom","SS",NA,0.123,NA,0.071,3,232,NA,43,NA,0.158,"Chl a (µg/L)",2,NA,0.637,NA,0.368,3,0.8,0.459,0.084,0.667
"212",212,217,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms 2-20um","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,1.696,"Chl a (µg/L)","biomass","biom","SS",NA,0.541,NA,0.312,3,232,NA,43,NA,1.436,"Chl a (µg/L)",2,NA,0.282,NA,0.163,3,0.8,0.431,-0.482,0.686
"213",213,222,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae >20um","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.805,"Chl a (µg/L)","biomass","biom","SS",NA,0.481,NA,0.278,3,232,NA,43,NA,0.252,"Chl a (µg/L)",2,NA,0.382,NA,0.221,3,0.8,0.434,-1.019,0.753
"214",214,227,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms >20um","phytoplankton",4,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,1.575,"Chl a (µg/L)","biomass","biom","SS",NA,0.154,NA,0.089,3,232,NA,43,NA,0.901,"Chl a (µg/L)",2,NA,0.947,NA,0.547,3,0.8,0.678,-0.795,0.719
"215",215,198,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Diatoms","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,7.211,"Chl a (µg/L)","biomass","biom","SS",NA,0.817,NA,0.472,3,232,NA,43,NA,3.621,"Chl a (µg/L)",2,NA,0.355,NA,0.205,3,0.8,0.63,-4.56,2.399
"216",216,203,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Green algae","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,1.2,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"217",217,208,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.068,"Chl a (µg/L)","biomass","biom","SS",NA,0.037,NA,0.021,3,232,NA,43,NA,0.306,"Chl a (µg/L)",2,NA,0.228,NA,0.132,3,0.8,0.163,1.166,0.78
"218",218,213,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae 2-20um","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.765,"Chl a (µg/L)","biomass","biom","SS",NA,0.439,NA,0.253,3,232,NA,43,NA,0.409,"Chl a (µg/L)",2,NA,0.729,NA,0.421,3,0.8,0.602,-0.473,0.685
"219",219,218,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms 2-20um","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,3.769,"Chl a (µg/L)","biomass","biom","SS",NA,0.759,NA,0.438,3,232,NA,43,NA,2.326,"Chl a (µg/L)",2,NA,0.669,NA,0.386,3,0.8,0.715,-1.614,0.884
"220",220,223,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae >20um","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,2.39,"Chl a (µg/L)","biomass","biom","SS",NA,0.727,NA,0.42,3,232,NA,43,NA,0.753,"Chl a (µg/L)",2,NA,0.509,NA,0.294,3,0.8,0.628,-2.087,1.03
"221",221,228,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms >20um","phytoplankton",5,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,3.451,"Chl a (µg/L)","biomass","biom","SS",NA,0.973,NA,0.562,3,232,NA,43,NA,1.037,"Chl a (µg/L)",2,NA,0.979,NA,0.565,3,0.8,0.976,-1.979,0.993
"222",222,199,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Diatoms","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,4.373,"Chl a (µg/L)","biomass","biom","SS",NA,0.65,NA,0.375,3,232,NA,43,NA,4.086,"Chl a (µg/L)",2,NA,0.147,NA,0.085,3,0.8,0.471,-0.487,0.686
"223",223,204,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Graph too cluttered to extract all data from","Graph too cluttered to extract all data from","Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Total Green algae","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,NA,NA,NA,2,539,NA,100,NA,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,232,NA,43,NA,1.275,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"224",224,209,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Picophytoplankton","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.241,"Chl a (µg/L)","biomass","biom","SS",NA,0.106,NA,0.061,3,232,NA,43,NA,0.534,"Chl a (µg/L)",2,NA,0.245,NA,0.141,3,0.8,0.189,1.242,0.795
"225",225,214,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae 2-20um","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,0.597,"Chl a (µg/L)","biomass","biom","SS",NA,0.321,NA,0.185,3,232,NA,43,NA,0.602,"Chl a (µg/L)",2,NA,0.686,NA,0.396,3,0.8,0.536,0.007,0.667
"226",226,219,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms 2-20um","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,2.31,"Chl a (µg/L)","biomass","biom","SS",NA,0.588,NA,0.339,3,232,NA,43,NA,2.37,"Chl a (µg/L)",2,NA,0.625,NA,0.361,3,0.8,0.607,0.079,0.667
"227",227,224,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Green algae >20um","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,1.13,"Chl a (µg/L)","biomass","biom","SS",NA,1.034,NA,0.597,3,232,NA,43,NA,0.629,"Chl a (µg/L)",2,NA,0.438,NA,0.253,3,0.8,0.794,-0.505,0.688
"228",228,229,"141","Reul, A; Munoz, M; Bautista, B; Neale, PJ; Sobrino, C; Mercado, JM; Segovia, M; Salles, S; Kulk, G; Leon, P; van de Poll, WH; Perez, E; Buma, A; Blanco, JM",2014,"Effect of CO2, nutrients and light on coastal plankton. III. Trophic cascade, size structure and composition","AQUATIC BIOLOGY",1,"Very cluttered graphs to interprete",NA,"Fig 5","fall","2012","Field","coastal",36.54,4.6,"Alboran Sea, Spain","Diatoms >20um","phytoplankton",6,"microcosm","Plastic cubitainers",20,NA,"yes","nutrients","shading screen",NA,NA,"PAR",21.5,NA,NA,36,0.14,0.8,0.14,0.8,NA,4,539,NA,100,NA,1.949,"Chl a (µg/L)","biomass","biom","SS",NA,0.469,NA,0.271,3,232,NA,43,NA,1.241,"Chl a (µg/L)",2,NA,0.87,NA,0.502,3,0.8,0.699,-0.81,0.721
"229",229,230,"142","Fielding, SR",2014,"Emiliania huxleyi population growth rate response to light and temperature: a synthesis","AQUATIC MICROBIAL ECOLOGY",1,NA,"Review and model, no experiment",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"230",230,231,"144","Kilroy, C; Bothwell, ML",2014,"Attachment and short-term stalk development of Didymosphenia geminata: effects of light, temperature and nutrients","DIATOM RESEARCH",1,NA,"Freshwater study on Didymosphenia geminata",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"231",231,232,"145","Chen, BB; Zou, DH",2014,"Growth and photosynthetic activity of Sargassum henslowianum (Fucales, Phaeophyta) seedlings in responses to different light intensities, temperatures and CO2 levels under laboratory conditions","MARINE BIOLOGY RESEARCH",1,"Brown macroalgae, precultured for 20 days prior experiment begin",NA,"Fig 1a",NA,NA,"Lab","coastal",23.33,116.92,"Nan'ao island, China","Sargassum henslowianum","macroalgae",10,"microcosm","Aquaria",1,NA,"no","nut_temp","reduced light","12",NA,NA,20,NA,NA,33,1,20,1,20,NA,4,120,NA,100,NA,1.427,"Growth rate (% µ / d)","growth rate","biom","dSS",NA,0.319,NA,0.184,3,20,NA,16.7,NA,3.431,"Growth rate (% µ / d)",2,NA,0.273,NA,0.158,3,0.8,0.297,5.4,3.097
"232",232,233,"145","Chen, BB; Zou, DH",2014,"Growth and photosynthetic activity of Sargassum henslowianum (Fucales, Phaeophyta) seedlings in responses to different light intensities, temperatures and CO2 levels under laboratory conditions","MARINE BIOLOGY RESEARCH",1,"Brown macroalgae, precultured for 20 days prior experiment begin",NA,"Fig 1a",NA,NA,"Lab","coastal",23.33,116.92,"Nan'ao island, China","Sargassum henslowianum","macroalgae",10,"microcosm","Aquaria",1,NA,"no","nut_temp","reduced light","12",NA,NA,20,NA,NA,33,1,20,1,20,NA,4,120,NA,100,NA,1.427,"Growth rate (% µ / d)","growth rate","biom","dSS",NA,0.319,NA,0.184,3,60,NA,50,NA,5.07,"Growth rate (% µ / d)",2,NA,0.759,NA,0.438,3,0.8,0.582,5.006,2.755
"233",233,234,"145","Chen, BB; Zou, DH",2014,"Growth and photosynthetic activity of Sargassum henslowianum (Fucales, Phaeophyta) seedlings in responses to different light intensities, temperatures and CO2 levels under laboratory conditions","MARINE BIOLOGY RESEARCH",1,"Brown macroalgae, precultured for 20 days prior experiment begin",NA,"Fig 1a",NA,NA,"Lab","coastal",23.33,116.92,"Nan'ao island, China","Sargassum henslowianum","macroalgae",10,"microcosm","Aquaria",1,NA,"no","nut_temp","reduced light","12",NA,NA,20,NA,NA,33,1,20,1,20,NA,4,120,NA,100,NA,2.095,"Germination vigour (%/d)","growth rate","biom","dSS",NA,0.577,NA,0.333,3,20,NA,16.7,NA,5.784,"Germination vigour (%/d)",2,NA,0.334,NA,0.193,3,0.8,0.471,6.26,3.932
"234",234,235,"145","Chen, BB; Zou, DH",2014,"Growth and photosynthetic activity of Sargassum henslowianum (Fucales, Phaeophyta) seedlings in responses to different light intensities, temperatures and CO2 levels under laboratory conditions","MARINE BIOLOGY RESEARCH",1,"Brown macroalgae, precultured for 20 days prior experiment begin",NA,"Fig 1a",NA,NA,"Lab","coastal",23.33,116.92,"Nan'ao island, China","Sargassum henslowianum","macroalgae",10,"microcosm","Aquaria",1,NA,"no","nut_temp","reduced light","12",NA,NA,20,NA,NA,33,1,20,1,20,NA,4,120,NA,100,NA,2.095,"Germination vigour (%/d)","growth rate","biom","dSS",NA,0.577,NA,0.333,3,60,NA,50,NA,3.871,"Germination vigour (%/d)",2,NA,0.364,NA,0.21,3,0.8,0.482,2.945,1.39
"235",235,236,"145","Chen, BB; Zou, DH",2014,"Growth and photosynthetic activity of Sargassum henslowianum (Fucales, Phaeophyta) seedlings in responses to different light intensities, temperatures and CO2 levels under laboratory conditions","MARINE BIOLOGY RESEARCH",1,"Brown macroalgae, precultured for 20 days prior experiment begin",NA,"Table 1",NA,NA,"Lab","coastal",23.33,116.92,"Nan'ao island, China","Sargassum henslowianum","macroalgae",10,"microcosm","Aquaria",1,NA,"no","nut_temp","reduced light","12",NA,NA,20,NA,NA,33,1,20,1,20,NA,4,120,NA,100,NA,15.25,"Net photosynthetic rate  (µmol O²/ g Fw/ h)","mass-specific production","phys","dQ",NA,2.57,NA,1.484,3,20,NA,16.7,NA,23.01,"Net photosynthetic rate  (µmol O²/ g Fw/ h)",1,NA,4.09,NA,2.361,3,0.8,3.416,1.818,0.942
"236",236,237,"145","Chen, BB; Zou, DH",2014,"Growth and photosynthetic activity of Sargassum henslowianum (Fucales, Phaeophyta) seedlings in responses to different light intensities, temperatures and CO2 levels under laboratory conditions","MARINE BIOLOGY RESEARCH",1,"Brown macroalgae, precultured for 20 days prior experiment begin",NA,"Table 1",NA,NA,"Lab","coastal",23.33,116.92,"Nan'ao island, China","Sargassum henslowianum","macroalgae",10,"microcosm","Aquaria",1,NA,"no","nut_temp","reduced light","12",NA,NA,20,NA,NA,33,1,20,1,20,NA,4,120,NA,100,NA,15.25,"Net photosynthetic rate  (µmol O²/ g Fw/ h)","mass-specific production","phys","dQ",NA,2.57,NA,1.484,3,60,NA,50,NA,34.05,"Net photosynthetic rate  (µmol O²/ g Fw/ h)",1,NA,5.72,NA,3.302,3,0.8,4.434,3.392,1.625
"237",237,238,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1ad",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",5,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,14731,"biovolume (cells / ml)","biomass","biom","SS",NA,2991,NA,2115,2,20,NA,16.7,NA,14547,"biovolume (cells / ml)",2,NA,1874,NA,1325,2,0.571,2495.792,-0.042,1
"238",238,244,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration","no STD or STE given","Fig 1ad",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",5,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,NA,NA,NA,2,120,NA,100,NA,14731,"biovolume (cells / ml)","biomass","biom","SS",NA,2991,NA,2115,2,NA,NA,NA,NA,NA,"biovolume (cells / ml)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"239",239,250,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",5,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,14731,"biovolume (cells / ml)","biomass","biom","SS",NA,2991,NA,2115,2,80,NA,66.7,NA,17405,"biovolume (cells / ml)",2,NA,1946,NA,1376,2,0.571,2523.192,0.606,1.046
"240",240,239,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration","no STD or STE given","Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",9,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,NA,NA,NA,2,120,NA,100,NA,17759,"biovolume (cells / ml)","biomass","biom","SS",NA,2324,NA,1643,2,NA,NA,NA,NA,NA,"biovolume (cells / ml)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"241",241,245,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration","no STD or STE given","Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",9,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,NA,NA,NA,2,120,NA,100,NA,17759,"biovolume (cells / ml)","biomass","biom","SS",NA,2324,NA,1643,2,NA,NA,NA,NA,NA,"biovolume (cells / ml)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"242",242,251,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",9,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,17759,"biovolume (cells / ml)","biomass","biom","SS",NA,2324,NA,1643,2,80,NA,66.7,NA,20324,"biovolume (cells / ml)",2,NA,1622,NA,1147,2,0.571,2003.979,0.731,1.067
"243",243,240,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration","no STD or STE given","Fig 1bd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",14,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,NA,NA,NA,2,120,NA,100,NA,31262,"biovolume (cells / ml)","biomass","biom","SS",NA,1164,NA,823,2,NA,NA,NA,NA,NA,"biovolume (cells / ml)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"244",244,246,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1bd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",14,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,31262,"biovolume (cells / ml)","biomass","biom","SS",NA,1164,NA,823,2,40,NA,33.3,NA,50000,"biovolume (cells / ml)",2,NA,2057,NA,1455,2,0.571,1671.249,6.407,6.131
"245",245,252,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",14,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,31262,"biovolume (cells / ml)","biomass","biom","SS",NA,1164,NA,823,2,80,NA,66.7,NA,27135,"biovolume (cells / ml)",2,NA,973,NA,688,2,0.571,1072.759,-2.198,1.604
"246",246,241,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1ad",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",20,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,45770,"biovolume (cells / ml)","biomass","biom","SS",NA,996,NA,704,2,20,NA,16.7,NA,33285,"biovolume (cells / ml)",2,NA,6792,NA,4803,2,0.571,4854.033,-1.47,1.27
"247",247,247,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1bd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",20,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,45770,"biovolume (cells / ml)","biomass","biom","SS",NA,996,NA,704,2,40,NA,33.3,NA,69543,"biovolume (cells / ml)",2,NA,1371,NA,969,2,0.571,1198.261,11.337,17.066
"248",248,253,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",20,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,45770,"biovolume (cells / ml)","biomass","biom","SS",NA,996,NA,704,2,80,NA,66.7,NA,56649,"biovolume (cells / ml)",2,NA,5837,NA,4127,2,0.571,4187.039,1.485,1.276
"249",249,242,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1ad",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",26,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,90347,"biovolume (cells / ml)","biomass","biom","SS",NA,664,NA,470,2,20,NA,16.7,NA,62093,"biovolume (cells / ml)",2,NA,5621,NA,3975,2,0.571,4002.283,-4.034,3.034
"250",250,248,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1bd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",26,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,90347,"biovolume (cells / ml)","biomass","biom","SS",NA,664,NA,470,2,40,NA,33.3,NA,124057,"biovolume (cells / ml)",2,NA,3429,NA,2425,2,0.571,2469.71,7.8,8.604
"251",251,254,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1cd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",26,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,90347,"biovolume (cells / ml)","biomass","biom","SS",NA,664,NA,470,2,80,NA,66.7,NA,121189,"biovolume (cells / ml)",2,NA,2595,NA,1835,2,0.571,1894.059,9.305,11.823
"252",252,243,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration","no STD or STE given","Fig 1ad",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",29,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,NA,NA,NA,2,120,NA,100,NA,75756,"biovolume (cells / ml)","biomass","biom","SS",NA,10300,NA,7283,2,NA,NA,NA,NA,NA,"biovolume (cells / ml)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"253",253,249,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration",NA,"Fig 1bd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",29,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,36.3,882,NA,4,120,NA,100,NA,75756,"biovolume (cells / ml)","biomass","biom","SS",NA,10300,NA,7283,2,40,NA,33.3,NA,102800,"biovolume (cells / ml)",2,NA,3771,NA,2666,2,0.571,7755.98,1.992,1.496
"254",254,255,"146","Lopez-Rosales, L; Gallardo-Rodriguez, JJ; Sanchez-Miron, A; Ceron-Garcia, MD; Belarbi, EH; Garcia-Camacho, F; Molina-Grima, E",2014,"Simultaneous Effect of Temperature and Irradiance on Growth and Okadaic Acid Production from the Marine Dinoflagellate Prorocentrum belizeanum","TOXINS",1,"Data not available for control or all treatments during the whole duration","no STD or STE given","Fig 1bd",NA,NA,"Lab","culture",NA,NA,NA,"Dinoflagellate, Prorocentrum belizeanum","phytobenthos",29,"microcosm","Polystyrene tissue T-flasks",0.015,NA,"unknown","temperature","reduced light","12",NA,NA,18,NA,55000,NA,36.3,882,NA,NA,NA,2,120,NA,100,NA,75756,"biovolume (cells / ml)","biomass","biom","SS",NA,10300,NA,7283,2,NA,NA,NA,NA,NA,"biovolume (cells / ml)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"255",255,256,"149","Wang, XD; Wang, Y; Ou, LJ",2014,"The roles of light-dark cycles in the growth of Phaeocystis globosa from the South China Sea: The cost of colony enlargement","JOURNAL OF SEA RESEARCH",1,NA,"No light intensity manipulation, only changes in light:dark cycle duration",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"256",256,257,"152","Benson, JL; Schlezinger, D; Howes, BL",2013,"Relationship between nitrogen concentration, light, and Zostera marina habitat quality and survival in southeastern Massachusetts estuaries","JOURNAL OF ENVIRONMENTAL MANAGEMENT",1,"eelgrass",NA,"Table 1","summer","2009","Field","coastal",41.6,-70.92,"Clark's Cove, USA","Zostera marina","seagrass",150,"field plot","no container",NA,4,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,91,NA,100,NA,-0.39,"Rate of shoot loss (shoot/day)","growth rate","biom","dSS",NA,0.4,NA,0.2,4,76,NA,84,NA,-0.42,"Rate of shoot loss (shoot/day)",2,NA,0.2,NA,0.1,4,0.87,0.316,-0.082,0.5
"257",257,258,"152","Benson, JL; Schlezinger, D; Howes, BL",2013,"Relationship between nitrogen concentration, light, and Zostera marina habitat quality and survival in southeastern Massachusetts estuaries","JOURNAL OF ENVIRONMENTAL MANAGEMENT",1,"eelgrass",NA,"Table 1","summer","2009","Field","coastal",41.6,-70.92,"Clark's Cove, USA","Zostera marina","seagrass",150,"field plot","no container",NA,4,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,91,NA,100,NA,-0.39,"Rate of shoot loss (shoot/day)","growth rate","biom","dSS",NA,0.4,NA,0.2,4,38,NA,42.3,NA,-0.85,"Rate of shoot loss (shoot/day)",2,NA,0.04,NA,0.02,4,0.87,0.284,-1.407,0.624
"258",258,259,"152","Benson, JL; Schlezinger, D; Howes, BL",2013,"Relationship between nitrogen concentration, light, and Zostera marina habitat quality and survival in southeastern Massachusetts estuaries","JOURNAL OF ENVIRONMENTAL MANAGEMENT",1,"eelgrass",NA,"Table 1","summer","2009","Field","coastal",41.6,-70.92,"Clark's Cove, USA","Zostera marina","seagrass",150,"field plot","no container",NA,4,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,91,NA,100,NA,-0.39,"Rate of shoot loss (shoot/day)","growth rate","biom","dSS",NA,0.4,NA,0.2,4,6,NA,7.1,NA,-1.13,"Rate of shoot loss (shoot/day)",2,NA,0.44,NA,0.22,4,0.87,0.42,-1.53,0.646
"259",259,266,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",4,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,0.464,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.011,NA,0.006,3,150,NA,50,NA,0.337,"Growth rate (µ/d)",2,NA,0.016,NA,0.009,3,0.8,0.014,-7.4,5.23
"260",260,260,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Fig 2ac",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",6,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,2.703,"Biomass (g/L)","biomass","biom","SS",NA,0.172,NA,0.099,3,150,NA,50,NA,2.288,"Biomass (g/L)",2,NA,0.323,NA,0.186,3,0.8,0.259,-1.283,0.804
"261",261,261,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Fig 2ac",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",8,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,2.723,"Biomass (g/L)","biomass","biom","SS",NA,0.258,NA,0.149,3,150,NA,50,NA,3.597,"Biomass (g/L)",2,NA,0.215,NA,0.124,3,0.8,0.237,2.944,1.389
"262",262,267,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",8,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,0.269,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.016,NA,0.009,3,150,NA,50,NA,0.249,"Growth rate (µ/d)",2,NA,0.026,NA,0.015,3,0.8,0.022,-0.741,0.712
"263",263,262,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Fig 2ac",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",10,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,2.722,"Biomass (g/L)","biomass","biom","SS",NA,0.258,NA,0.149,3,150,NA,50,NA,3.271,"Biomass (g/L)",2,NA,0.302,NA,0.174,3,0.8,0.281,1.564,0.87
"264",264,263,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Fig 2ac",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",12,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,2.613,"Biomass (g/L)","biomass","biom","SS",NA,0.451,NA,0.26,3,150,NA,50,NA,3.44,"Biomass (g/L)",2,NA,0.215,NA,0.124,3,0.8,0.353,1.873,0.959
"265",265,268,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",12,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,0.169,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.029,NA,0.017,3,150,NA,50,NA,0.161,"Growth rate (µ/d)",2,NA,0.021,NA,0.012,3,0.8,0.025,-0.253,0.672
"266",266,264,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Fig 2ac",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",14,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,2.224,"Biomass (g/L)","biomass","biom","SS",NA,0.151,NA,0.087,3,150,NA,50,NA,3.265,"Biomass (g/L)",2,NA,0.151,NA,0.087,3,0.8,0.151,5.515,3.201
"267",267,265,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Fig 2ac",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",15,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,2.179,"Biomass (g/L)","biomass","biom","SS",NA,0.237,NA,0.137,3,150,NA,50,NA,2.939,"Biomass (g/L)",2,NA,0.323,NA,0.186,3,0.8,0.283,2.146,1.051
"268",268,269,"157","Xia, S; Wan, LL; Li, AF; Sang, M; Zhang, CW",2013,"Effects of nutrients and light intensity on the growth and biochemical composition of a marine microalga Odontella aurita","CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY",1,NA,NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Diatom, Odontella aurita","phytoplankton",15,"microcosm","Cylindrical glass column",0.4,NA,"no","nutrients","reduced light","24",NA,NA,25,NA,NA,NA,360,3530,360,3530,110,5,300,NA,100,NA,0.126,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.126,NA,0.073,3,150,NA,50,NA,0.127,"Growth rate (µ/d)",2,NA,0.012,NA,0.007,3,0.8,0.089,0.009,0.667
"269",269,270,"165","Kulk, G; van de Poll, WH; Visser, RJW; Buma, AGJ",2013,"Low nutrient availability reduces high-irradiance-induced viability loss in oceanic phytoplankton","LIMNOLOGY AND OCEANOGRAPHY",1,NA,"Light treatment (500µmol/s/m²) duration only 4h",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"270",270,271,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Achnanthes sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, blue","12",NA,"450",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,5.87,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.602,NA,0.269,5,70,NA,100,NA,6.27,"Net photosynthetic rate (O2/cell/h)",1,NA,0.628,NA,0.281,5,0.903,0.615,0.587,0.417
"271",271,272,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Achnanthes sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, yellow","12",NA,"590",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,5.87,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.602,NA,0.269,5,70,NA,100,NA,1.14,"Net photosynthetic rate (O2/cell/h)",1,NA,0.429,NA,0.192,5,0.903,0.523,-8.173,3.74
"272",272,273,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Achnanthes sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, red","12",NA,"650",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,5.87,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.602,NA,0.269,5,70,NA,100,NA,2.69,"Net photosynthetic rate (O2/cell/h)",1,NA,0.28,NA,0.125,5,0.903,0.469,-6.118,2.272
"273",273,274,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","No TRT values available","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Achnanthes sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none",NA,"12",NA,"PAR",20,8.2,NA,30,36.3,882,NA,NA,107,3,70,NA,100,NA,5.87,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.602,NA,0.269,5,70,NA,100,NA,NA,"Net photosynthetic rate (O2/cell/h)",1,NA,NA,NA,NA,5,0.903,NA,NA,NA
"274",274,275,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Amphora sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, blue","12",NA,"450",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,5.99,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.543,NA,0.243,5,70,NA,100,NA,7.2,"Net photosynthetic rate (O2/cell/h)",1,NA,0.643,NA,0.288,5,0.903,0.595,1.836,0.569
"275",275,276,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Amphora sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, yellow","12",NA,"590",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,5.99,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.543,NA,0.243,5,70,NA,100,NA,2.52,"Net photosynthetic rate (O2/cell/h)",1,NA,0.221,NA,0.099,5,0.903,0.415,-7.561,3.258
"276",276,277,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Amphora sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, red","12",NA,"650",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,5.99,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.543,NA,0.243,5,70,NA,100,NA,2.78,"Net photosynthetic rate (O2/cell/h)",1,NA,0.25,NA,0.112,5,0.903,0.423,-6.859,2.752
"277",277,278,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","No TRT values available","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Amphora sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none",NA,"12",NA,"PAR",20,8.2,NA,30,36.3,882,NA,NA,107,3,70,NA,100,NA,5.99,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.543,NA,0.243,5,70,NA,100,NA,NA,"Net photosynthetic rate (O2/cell/h)",1,NA,NA,NA,NA,5,0.903,NA,NA,NA
"278",278,279,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Navicula sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, blue","12",NA,"450",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,8.39,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.854,NA,0.382,5,70,NA,100,NA,9.88,"Net photosynthetic rate (O2/cell/h)",1,NA,1.008,NA,0.451,5,0.903,0.934,1.441,0.504
"279",279,280,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Navicula sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, yellow","12",NA,"590",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,8.39,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.854,NA,0.382,5,70,NA,100,NA,3.13,"Net photosynthetic rate (O2/cell/h)",1,NA,0.312,NA,0.14,5,0.903,0.643,-7.39,3.13
"280",280,281,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Navicula sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, red","12",NA,"650",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,8.39,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.854,NA,0.382,5,70,NA,100,NA,4.21,"Net photosynthetic rate (O2/cell/h)",1,NA,0.435,NA,0.195,5,0.903,0.678,-5.571,1.952
"281",281,282,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","No TRT values available","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Navicula sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none",NA,"12",NA,"PAR",20,8.2,NA,30,36.3,882,NA,NA,107,3,70,NA,100,NA,8.39,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.854,NA,0.382,5,70,NA,100,NA,NA,"Net photosynthetic rate (O2/cell/h)",1,NA,NA,NA,NA,5,0.903,NA,NA,NA
"282",282,283,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Nitzschia sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, blue","12",NA,"450",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,10.02,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.807,NA,0.361,5,70,NA,100,NA,12.97,"Net photosynthetic rate (O2/cell/h)",1,NA,0.72,NA,0.322,5,0.903,0.765,3.484,1.007
"283",283,284,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Nitzschia sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, yellow","12",NA,"590",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,10.02,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.807,NA,0.361,5,70,NA,100,NA,5.56,"Net photosynthetic rate (O2/cell/h)",1,NA,0.562,NA,0.251,5,0.903,0.695,-5.793,2.078
"284",284,285,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Nitzschia sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none","monochromatic irradiance, red","12",NA,"650",20,8.2,NA,30,36.3,882,36.3,882,107,5,70,NA,100,NA,10.02,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.807,NA,0.361,5,70,NA,100,NA,7.47,"Net photosynthetic rate (O2/cell/h)",1,NA,0.647,NA,0.289,5,0.903,0.731,-3.149,0.896
"285",285,286,"167","Kwon, HK; Oh, SJ; Yang, HS; Kim, DM; Kang, IJ; Oshima, Y",2013,"Laboratory Study for the Phytoremediation of Eutrophic Coastal Sediment Using Benthic Microalgae and Light Emitting Diode (LED)","JOURNAL OF THE FACULTY OF AGRICULTURE KYUSHU UNIVERSITY",1,"Same light intensity for both CTRL and TRT (70 µmol/s/m²). PAR used as control. Monochromatic wavelenghts as treatments: blue, yellow and red.","No TRT values available","Fig 2","spring","2010","Lab","coastal",35.12,128.6,"Masan Bay, South Korea","Nitzschia sp.","phytobenthos",1,"microcosm","Bottle",0.05,NA,"unknown","none",NA,"12",NA,"PAR",20,8.2,NA,30,36.3,882,NA,NA,107,3,70,NA,100,NA,10.02,"Net photosynthetic rate (O2/cell/h)","mass-specific production","phys","dQ",NA,0.807,NA,0.361,5,70,NA,100,NA,NA,"Net photosynthetic rate (O2/cell/h)",1,NA,NA,NA,NA,5,0.903,NA,NA,NA
"286",286,287,"168","Nejrup, LB; Staehr, PA; Thomsen, MS",2013,"Temperature- and light-dependent growth and metabolism of the invasive red algae Gracilaria vermiculophylla - a comparison with two native macroalgae","EUROPEAN JOURNAL OF PHYCOLOGY",1,"Six different irradiances and temperatures as treatment, chosen temperature 20C, since most studies around 20C",NA,"Fig 1b","fall","2007","Lab","coastal",55.3,10.77,"Fyn, Denmark","Gracilaria vermiculophylla","macroalgae",42,"microcosm","Plastic cubitainers",1.7,NA,"no","temperature","shading screen","16",NA,"PAR",20,NA,NA,20,NA,NA,NA,NA,NA,0,225,NA,100,NA,0.043,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.003,NA,0.002,3,80,NA,35.6,NA,0.031,"Growth rate (µ/d)",2,NA,0.005,NA,0.003,3,0.8,0.004,-2.174,1.061
"287",287,288,"168","Nejrup, LB; Staehr, PA; Thomsen, MS",2013,"Temperature- and light-dependent growth and metabolism of the invasive red algae Gracilaria vermiculophylla - a comparison with two native macroalgae","EUROPEAN JOURNAL OF PHYCOLOGY",1,"Six different irradiances and temperatures as treatment, chosen temperature 20C, since most studies around 20C",NA,"Fig 1b","fall","2007","Lab","coastal",55.3,10.77,"Fyn, Denmark","Gracilaria vermiculophylla","macroalgae",42,"microcosm","Plastic cubitainers",1.7,NA,"no","temperature","shading screen","16",NA,"PAR",20,NA,NA,20,NA,NA,NA,NA,NA,0,225,NA,100,NA,0.043,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.003,NA,0.002,3,34,NA,15.1,NA,0.023,"Growth rate (µ/d)",2,NA,0.003,NA,0.002,3,0.8,0.003,-4.619,2.444
"288",288,289,"168","Nejrup, LB; Staehr, PA; Thomsen, MS",2013,"Temperature- and light-dependent growth and metabolism of the invasive red algae Gracilaria vermiculophylla - a comparison with two native macroalgae","EUROPEAN JOURNAL OF PHYCOLOGY",1,"Six different irradiances and temperatures as treatment, chosen temperature 20C, since most studies around 20C",NA,"Fig 1b","fall","2007","Lab","coastal",55.3,10.77,"Fyn, Denmark","Gracilaria vermiculophylla","macroalgae",42,"microcosm","Plastic cubitainers",1.7,NA,"no","temperature","shading screen","16",NA,"PAR",20,NA,NA,20,NA,NA,NA,NA,NA,0,225,NA,100,NA,0.043,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.003,NA,0.002,3,16,NA,7.1,NA,0.014,"Growth rate (µ/d)",2,NA,0.003,NA,0.002,3,0.8,0.003,-6.697,4.404
"289",289,290,"168","Nejrup, LB; Staehr, PA; Thomsen, MS",2013,"Temperature- and light-dependent growth and metabolism of the invasive red algae Gracilaria vermiculophylla - a comparison with two native macroalgae","EUROPEAN JOURNAL OF PHYCOLOGY",1,"Six different irradiances and temperatures as treatment, chosen temperature 20C, since most studies around 20C",NA,"Fig 1b","fall","2007","Lab","coastal",55.3,10.77,"Fyn, Denmark","Gracilaria vermiculophylla","macroalgae",42,"microcosm","Plastic cubitainers",1.7,NA,"no","temperature","shading screen","16",NA,"PAR",20,NA,NA,20,NA,NA,NA,NA,NA,0,225,NA,100,NA,0.043,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.003,NA,0.002,3,9,NA,4,NA,0.012,"Growth rate (µ/d)",2,NA,0.002,NA,0.001,3,0.8,0.003,-9.056,7.5
"290",290,291,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Phytoplankton 0,22-1 µm","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,9.8,440,"Chl a (ng / L)","biomass","biom","SS",8.008,74.953,1.1,53,2,24,NA,20,NA,160,"Chl a (ng / L)",2,NA,141.421,NA,100,2,0.571,113.177,-1.414,1.25
"291",291,292,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Phytoplankton 0,22-1 µm","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,NA,440,"Chl a (ng / L)","biomass","biom","SS",NA,74.953,NA,53,2,2.4,NA,2,NA,96,"Chl a (ng / L)",2,NA,4.667,NA,3.3,2,0.571,53.103,-3.702,2.713
"292",292,293,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Phytoplankton 1-5 µm","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,19,260,"Chl a (ng / L)","biomass","biom","SS",10.054,39.598,1.9,28,2,24,NA,20,NA,150,"Chl a (ng / L)",2,NA,1.004,NA,0.71,2,0.571,28.009,-2.244,1.63
"293",293,294,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Phytoplankton 1-5 µm","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,NA,260,"Chl a (ng / L)","biomass","biom","SS",NA,39.598,NA,28,2,2.4,NA,2,NA,50,"Chl a (ng / L)",2,NA,7.778,NA,5.5,2,0.571,28.535,-4.205,3.211
"294",294,295,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Phytoplankton >5 µm","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,13,160,"Chl a (ng / L)","biomass","biom","SS",1.875,10.748,0.68,7.6,2,24,NA,20,NA,81,"Chl a (ng / L)",2,NA,12.728,NA,9,2,0.571,11.78,-3.832,2.836
"295",295,296,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Phytoplankton >5 µm","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,NA,160,"Chl a (ng / L)","biomass","biom","SS",NA,10.748,NA,7.6,2,2.4,NA,2,NA,29,"Chl a (ng / L)",2,NA,0.948,NA,0.67,2,0.571,7.629,-9.812,13.033
"296",296,297,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Total phytoplankton","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,42,860,"Chl a (ng / L)","biomass","biom","SS",31.132,125.865,3.3,89,2,24,NA,20,NA,390,"Chl a (ng / L)",2,NA,130.108,NA,92,2,0.571,128.004,-2.098,1.55
"297",297,298,"171","Taylor, RL; Semeniuk, DM; Payne, CD; Zhou, J; Tremblay, JE; Cullen, JT; Maldonado, MT",2013,"Colimitation by light, nitrate, and iron in the Beaufort Sea in late summer","JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS",1,NA,NA,"Table 3","fall","2009","Field","offshore",71.1,-139.15,"Beaufort Sea, Canada","Total phytoplankton","phytoplankton",8,"microcosm","Plastic cubitainers",10,NA,"unknown","nutrients","shading screen","natural",240,"PAR",1.1,NA,NA,25.6,0.66,0.09,0.66,0.09,1.8,5,120,NA,100,NA,860,"Chl a (ng / L)","biomass","biom","SS",NA,125.865,NA,89,2,2.4,NA,2,NA,180,"Chl a (ng / L)",2,NA,13.435,NA,9.5,2,0.571,89.506,-4.341,3.356
"298",298,299,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 960 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.053,"Net photosynthetic rate (µl O2/ mg dry mass / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,65,NA,52,NA,0.107,"Net photosynthetic rate (µl O2/ mg dry mass / h)",1,NA,0.002,NA,0.001,4,0.87,0.002,23.478,34.952
"299",299,300,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 960 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.053,"Net photosynthetic rate (µl O2/ mg dry mass / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,5,NA,4,NA,0.216,"Net photosynthetic rate (µl O2/ mg dry mass / h)",1,NA,0.038,NA,0.019,4,0.87,0.027,5.268,2.234
"300",300,301,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter.  10 min irradiance at 353 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.049,"Net photosynthetic rate (µl O2/ mg dry mass / h)","mass-specific production","phys","dQ",NA,0.006,NA,0.003,4,65,NA,52,NA,0.092,"Net photosynthetic rate (µl O2/ mg dry mass / h)",1,NA,0.008,NA,0.004,4,0.87,0.007,5.288,2.248
"301",301,302,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter.  10 min irradiance at 353 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.049,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.006,NA,0.003,4,5,NA,4,NA,0.198,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.03,NA,0.015,4,0.87,0.022,5.989,2.742
"302",302,303,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 157 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.02,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.01,NA,0.005,4,65,NA,52,NA,0.071,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.006,NA,0.003,4,0.87,0.008,5.378,2.308
"303",303,304,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 157 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.02,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.01,NA,0.005,4,5,NA,4,NA,0.196,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.012,NA,0.006,4,0.87,0.011,13.856,12.499
"304",304,305,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 61 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.001,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.004,NA,0.002,4,65,NA,52,NA,0.027,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.012,NA,0.006,4,0.87,0.009,2.528,0.899
"305",305,306,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 5",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 61 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.001,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.004,NA,0.002,4,5,NA,4,NA,0.135,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.012,NA,0.006,4,0.87,0.009,13.028,11.107
"306",306,307,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 960 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.075,"Net photosynthetic rate (µl O2/ mg dry mass / h)","mass-specific production","phys","dQ",NA,0.004,NA,0.002,4,65,NA,52,NA,0.084,"Net photosynthetic rate (µl O2/ mg dry mass / h)",1,NA,0.006,NA,0.003,4,0.87,0.005,1.535,0.647
"307",307,308,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 960 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.075,"Net photosynthetic rate (µl O2/ mg dry mass / h)","mass-specific production","phys","dQ",NA,0.004,NA,0.002,4,5,NA,4,NA,0.084,"Net photosynthetic rate (µl O2/ mg dry mass / h)",1,NA,0.006,NA,0.003,4,0.87,0.005,1.535,0.647
"308",308,309,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter.  10 min irradiance at 353 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.07,"Net photosynthetic rate (µl O2/ mg dry mass / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,65,NA,52,NA,0.072,"Net photosynthetic rate (µl O2/ mg dry mass / h)",1,NA,0.006,NA,0.003,4,0.87,0.004,0.389,0.509
"309",309,310,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter.  10 min irradiance at 353 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.07,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,5,NA,4,NA,0.072,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.006,NA,0.003,4,0.87,0.004,0.389,0.509
"310",310,311,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 157 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.028,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.004,NA,0.002,4,65,NA,52,NA,0.057,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.004,NA,0.002,4,0.87,0.004,6.304,2.984
"311",311,312,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 157 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.028,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.004,NA,0.002,4,5,NA,4,NA,0.057,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.004,NA,0.002,4,0.87,0.004,6.304,2.984
"312",312,313,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 61 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.001,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,65,NA,52,NA,0.021,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.002,NA,0.001,4,0.87,0.002,8.696,5.226
"313",313,314,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 61 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,0.001,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,5,NA,4,NA,0.021,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.002,NA,0.001,4,0.87,0.002,8.696,5.226
"314",314,315,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 29 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,-0.012,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,65,NA,52,NA,-0.002,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.002,NA,0.001,4,0.87,0.002,4.348,1.681
"315",315,316,"175","Jodlowska, S; Latala, A",2013,"Combined effects of light and temperature on growth, photosynthesis, and pigment content in the mat-forming cyanobacterium Geitlerinema amphibium","PHOTOSYNTHETICA",1,"Preacclimated for 7 days prior to experiment. Net photosynthetic rate measured after 10 min illumination at each irradiance 960, 353, 157, 61 umol","Different irradiances used for growing and measuring photosynthetic rate","Fig 6",NA,NA,"Lab","coastal",54.59,18.57,"Puck Bay, Poland","Geitlerinema amphinium","phytobenthos",14,"microcosm","Erlenmeyer flask",0.15,NA,"no","temperature","neutral density shading filter. 10 min irradiance at 29 µmol m s","16",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,125,NA,100,NA,-0.012,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)","mass-specific production","phys","dQ",NA,0.002,NA,0.001,4,5,NA,4,NA,-0.002,"Net photosynthetic rate (µl O2/ µg (Chl a) / h)",1,NA,0.002,NA,0.001,4,0.87,0.002,4.348,1.681
"316",316,317,"176","Gustafsson, C; Bostrom, C",2013,"Influence of Neighboring Plants on Shading Stress Resistance and Recovery of Eelgrass, Zostera marina L","PLOS ONE",1,"seagrass","No Biomass data were given, only ratios between shoot and root",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"317",317,318,"183","Gali, M; Simo, R; Perez, GL; Ruiz-Gonzalez, C; Sarmento, H; Royer, SJ; Fuentes-Lema, A; Gasol, JM",2013,"Differential response of planktonic primary, bacterial, and dimethylsulfide production rates to static vs. dynamic light exposure in upper mixed-layer summer sea waters","BIOGEOSCIENCES",1,NA,"no replicates, only 6 h of incubation",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"318",318,319,"184","Villazan, B; Pedersen, MF; Brun, FG; Vergara, JJ",2013,"Elevated ammonium concentrations and low light form a dangerous synergy for eelgrass Zostera marina","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 1B","fall","2013","Lab","coastal",55.83,11.81,"Isefjorden, Denmark","Zostera marina","seagrass",35,"mesocosm","Aquaria",20,NA,"unknown","none","reduced light","16",NA,NA,15,NA,NA,20,NA,NA,NA,NA,NA,0,70,NA,100,NA,22.825,"Net production (mg freshweight/day)","area-specific production","biom","dSS",NA,8.36,NA,4.829,3,26,NA,37.1,NA,14.715,"Net production (mg freshweight/day)",2,NA,9.153,NA,5.285,3,0.8,8.768,-0.74,0.712
"319",319,320,"187","Fox, AD; Meng, F; Shen, X; Yang, X; Yang, W; Cao, L",2013,"Effects of shading on Vallisneria natans (Lour.) H. Hara growth","KNOWLEDGE AND MANAGEMENT OF AQUATIC ECOSYSTEMS",1,"seagrass","Freshwater species",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"320",320,321,"191","Ukabi, S; Dubinsky, Z; Steinberger, Y; Israel, A",2013,"Temperature and irradiance effects on growth and photosynthesis of Caulerpa (Chlorophyta) species from the eastern Mediterranean","AQUATIC BOTANY",1,"macroalgae","It is not given what the error bars represent",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"321",321,322,"195","Mendes, LF; Vale, LAS; Martins, AP; Yokoya, NS; Marinho-Soriano, E; Colepicolo, P",2012,"Influence of temperature, light and nutrients on the growth rates of the macroalga Gracilaria domingensis in synthetic seawater using experimental design","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae","no replicates",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"322",322,323,"202","Mvungi, EF; Lyimo, TJ; Bjork, M",2012,"When Zostera marina is intermixed with Ulva, its photosynthesis is reduced by increased pH and lower light, but not by changes in light quality","AQUATIC BOTANY",1,"seagrass",NA,"Fig 3","fall","2012","Lab","coastal",58.25,11.45,"Sweden West Coast","Zostera marina","seagrass",5,"incubation",NA,NA,NA,"unknown","none",NA,NA,NA,NA,11,NA,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25.305,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.5,NA,2.572,20,250,NA,50,NA,24.18,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,7.892,NA,1.765,20,0.98,9.864,-0.112,0.1
"323",323,324,"202","Mvungi, EF; Lyimo, TJ; Bjork, M",2012,"When Zostera marina is intermixed with Ulva, its photosynthesis is reduced by increased pH and lower light, but not by changes in light quality","AQUATIC BOTANY",1,"seagrass",NA,"Fig 3","fall","2012","Lab","coastal",58.25,11.45,"Sweden West Coast","Zostera marina","seagrass",5,"incubation",NA,NA,NA,"unknown","none",NA,NA,NA,NA,11,NA,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25.305,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.5,NA,2.572,20,100,NA,20,NA,18.236,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,2.809,NA,0.628,20,0.98,8.373,-0.827,0.109
"324",324,325,"202","Mvungi, EF; Lyimo, TJ; Bjork, M",2012,"When Zostera marina is intermixed with Ulva, its photosynthesis is reduced by increased pH and lower light, but not by changes in light quality","AQUATIC BOTANY",1,"seagrass",NA,"Fig 3","fall","2012","Lab","coastal",58.25,11.45,"Sweden West Coast","Zostera marina","seagrass",5,"incubation",NA,NA,NA,"unknown","none",NA,NA,NA,NA,11,NA,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25.305,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.5,NA,2.572,20,50,NA,10,NA,11.748,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,1.471,NA,0.329,20,0.98,8.2,-1.62,0.133
"325",325,326,"202","Mvungi, EF; Lyimo, TJ; Bjork, M",2012,"When Zostera marina is intermixed with Ulva, its photosynthesis is reduced by increased pH and lower light, but not by changes in light quality","AQUATIC BOTANY",1,"seagrass",NA,"Fig 3","fall","2012","Lab","coastal",58.25,11.45,"Sweden West Coast","Zostera marina","seagrass",5,"incubation",NA,NA,NA,"unknown","none",NA,NA,NA,NA,11,NA,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25.305,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.5,NA,2.572,20,25,NA,5,NA,6.634,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,0.535,NA,0.12,20,0.98,8.143,-2.247,0.163
"326",326,327,"202","Mvungi, EF; Lyimo, TJ; Bjork, M",2012,"When Zostera marina is intermixed with Ulva, its photosynthesis is reduced by increased pH and lower light, but not by changes in light quality","AQUATIC BOTANY",1,"seagrass",NA,"Fig 3","fall","2012","Lab","coastal",58.25,11.45,"Sweden West Coast","Zostera marina","seagrass",5,"incubation",NA,NA,NA,"unknown","none",NA,NA,NA,NA,11,NA,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25.305,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.5,NA,2.572,20,10,NA,2,NA,2.866,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,0.535,NA,0.12,20,0.98,8.143,-2.701,0.191
"327",327,328,"212","Hoogstraten, A; Timmermans, KR; de Baar, HJW",2012,"MORPHOLOGICAL AND PHYSIOLOGICAL EFFECTS IN PROBOSCIA ALATA (BACILLARIOPHYCEAE) GROWN UNDER DIFFERENT LIGHT AND CO2 CONDITIONS OF THE MODERN SOUTHERN OCEAN","JOURNAL OF PHYCOLOGY",1,"data for medium CO2 treatment were extracted; cell abundances in SUP 1 given, but not readily visible;semicontinuous growth",NA,"Fig 3",NA,NA,"Lab","coastal",NA,NA,NA,"Proboscia alata","phytoplankton",5,"microcosm","polymethylmethacrylate (PMMA) culture vessels",6,NA,"no","nutrients","reduced light","16",NA,NA,3,NA,NA,NA,3.75,60,3.75,60,NA,4,240,NA,100,NA,0.582,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.309,NA,0.155,4,40,NA,16.7,NA,0.568,"Growth rate (µ/d)",2,NA,0.227,NA,0.114,4,0.87,0.271,-0.044,0.5
"328",328,329,"212","Hoogstraten, A; Timmermans, KR; de Baar, HJW",2012,"MORPHOLOGICAL AND PHYSIOLOGICAL EFFECTS IN PROBOSCIA ALATA (BACILLARIOPHYCEAE) GROWN UNDER DIFFERENT LIGHT AND CO2 CONDITIONS OF THE MODERN SOUTHERN OCEAN","JOURNAL OF PHYCOLOGY",1,"data for medium CO2 treatment were extracted; cell abundances in SUP 1 given, but not readily visible;semicontinuous growth",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Proboscia alata","phytoplankton",5,"microcosm","polymethylmethacrylate (PMMA) culture vessels",6,NA,"no","nutrients","reduced light","16",NA,NA,3,NA,NA,NA,3.75,60,3.75,60,NA,4,240,NA,100,NA,0.69,"Fv/Fm","quantum yield","phys","dQ",NA,0.03,NA,0.011,8,40,NA,16.7,NA,0.69,"Fv/Fm",1,NA,0.05,NA,0.018,8,0.945,0.041,0,0.25
"329",329,330,"212","Hoogstraten, A; Timmermans, KR; de Baar, HJW",2012,"MORPHOLOGICAL AND PHYSIOLOGICAL EFFECTS IN PROBOSCIA ALATA (BACILLARIOPHYCEAE) GROWN UNDER DIFFERENT LIGHT AND CO2 CONDITIONS OF THE MODERN SOUTHERN OCEAN","JOURNAL OF PHYCOLOGY",1,"data for medium CO2 treatment were extracted; cell abundances in SUP 1 given, but not readily visible;semicontinuous growth",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Proboscia alata","phytoplankton",5,"microcosm","polymethylmethacrylate (PMMA) culture vessels",6,NA,"no","nutrients","reduced light","16",NA,NA,3,NA,NA,NA,3.75,60,3.75,60,NA,4,240,NA,100,NA,99.1,"cellular Chl a (pg/cell)","cellular content","phys","Q",NA,14.6,NA,6.529,5,40,NA,16.7,NA,91.4,"cellular Chl a (pg/cell)",1,NA,16.5,NA,7.379,5,0.903,15.579,-0.446,0.41
"330",330,331,"212","Hoogstraten, A; Timmermans, KR; de Baar, HJW",2012,"MORPHOLOGICAL AND PHYSIOLOGICAL EFFECTS IN PROBOSCIA ALATA (BACILLARIOPHYCEAE) GROWN UNDER DIFFERENT LIGHT AND CO2 CONDITIONS OF THE MODERN SOUTHERN OCEAN","JOURNAL OF PHYCOLOGY",1,"data for medium CO2 treatment were extracted; cell abundances in SUP 1 given, but not readily visible;semicontinuous growth",NA,"Fig 4",NA,NA,"Lab","coastal",NA,NA,NA,"Proboscia alata","phytoplankton",5,"microcosm","polymethylmethacrylate (PMMA) culture vessels",6,NA,"no","nutrients","reduced light","16",NA,NA,3,NA,NA,NA,3.75,60,3.75,60,NA,4,240,NA,100,NA,0.001,"cellular POC (pmol/cell)","cellular content","phys","Q",NA,NA,NA,NA,3,40,NA,16.7,NA,0.001,"cellular POC (pmol/cell)",1,NA,NA,NA,NA,4,0.842,NA,NA,NA
"331",331,332,"212","Hoogstraten, A; Timmermans, KR; de Baar, HJW",2012,"MORPHOLOGICAL AND PHYSIOLOGICAL EFFECTS IN PROBOSCIA ALATA (BACILLARIOPHYCEAE) GROWN UNDER DIFFERENT LIGHT AND CO2 CONDITIONS OF THE MODERN SOUTHERN OCEAN","JOURNAL OF PHYCOLOGY",1,"data for medium CO2 treatment were extracted; cell abundances in SUP 1 given, but not readily visible;semicontinuous growth",NA,"Table 2",NA,NA,"Lab","coastal",NA,NA,NA,"Proboscia alata","phytoplankton",5,"microcosm","polymethylmethacrylate (PMMA) culture vessels",6,NA,"no","nutrients","reduced light","16",NA,NA,3,NA,NA,NA,3.75,60,3.75,60,NA,4,240,NA,100,NA,159.7,"biovolume/cell (µm3)","biomass","biom","SS",NA,54.3,NA,5.154,111,40,NA,16.7,NA,154.1,"biovolume/cell (µm3)",2,NA,59.5,NA,5.218,130,0.997,57.165,-0.098,0.017
"332",332,333,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","9",NA,NA,18,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.239,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.045,NA,0.018,6,50,NA,25,NA,0.177,"Growth rate (µ/d)",2,NA,0.017,NA,0.007,6,0.923,0.034,-1.676,0.45
"333",333,334,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","9",NA,NA,22,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.409,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.047,NA,0.019,6,50,NA,25,NA,0.234,"Growth rate (µ/d)",2,NA,0.024,NA,0.01,6,0.923,0.037,-4.32,1.111
"334",334,335,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","9",NA,NA,26,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.324,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.026,NA,0.011,6,50,NA,25,NA,0.213,"Growth rate (µ/d)",2,NA,0.035,NA,0.014,6,0.923,0.031,-3.298,0.787
"335",335,336,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","12",NA,NA,18,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.485,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.09,NA,0.037,6,50,NA,25,NA,0.496,"Growth rate (µ/d)",2,NA,0.116,NA,0.047,6,0.923,0.104,0.105,0.334
"336",336,337,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","12",NA,NA,22,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.577,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.104,NA,0.042,6,50,NA,25,NA,0.388,"Growth rate (µ/d)",2,NA,0.059,NA,0.024,6,0.923,0.085,-2.064,0.511
"337",337,338,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","12",NA,NA,26,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.827,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.076,NA,0.031,6,50,NA,25,NA,0.558,"Growth rate (µ/d)",2,NA,0.033,NA,0.014,6,0.923,0.058,-4.261,1.09
"338",338,339,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","15",NA,NA,18,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.35,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.04,NA,0.016,6,50,NA,25,NA,0.47,"Growth rate (µ/d)",2,NA,0.057,NA,0.023,6,0.923,0.049,2.264,0.547
"339",339,340,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","15",NA,NA,22,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.615,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.026,NA,0.011,6,50,NA,25,NA,0.489,"Growth rate (µ/d)",2,NA,0.014,NA,0.006,6,0.923,0.021,-5.522,1.604
"340",340,341,"215","Scalco, E; Brunet, C; Marino, F; Rossi, R; Soprano, V; Zingone, A; Montresor, M",2012,"Growth and toxicity responses of Mediterranean Ostreopsis cf. ovata to seasonal irradiance and temperature conditions","HARMFUL ALGAE",1,"Data for 14C and 30C were not extracted, since not for all day lengths data were available",NA,"Fig 1",NA,NA,"Lab","coastal",40.47,14.11,"Thyrrenian Sea, Italy","Ostreopsis cf. Ovata","phytobenthos",19,"microcosm","Culture well plates",0.005,NA,"no","none","reduced light","15",NA,NA,26,NA,NA,36,NA,0.441,NA,0.441,NA,2,200,NA,100,NA,0.473,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.059,NA,0.024,6,50,NA,25,NA,0.511,"Growth rate (µ/d)",2,NA,0.078,NA,0.032,6,0.923,0.069,0.505,0.344
"341",341,342,"216","Mellard, JP; Yoshiyama, K; Klausmeier, CA; Litchman, E",2012,"Experimental test of phytoplankton competition for nutrients and light in poorly mixed water columns","ECOLOGICAL MONOGRAPHS",1,NA,"Freshwater species",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"342",342,353,"222","Yun, MS; Chung, KH; Zimmermann, S; Zhao, JP; Joo, HM; Lee, SH",2012,"Phytoplankton productivity and its response to higher light levels in the Canada Basin","POLAR BIOLOGY",1,"Data in table were treated as replicates, values below 0.001 are treated as 0.001",NA,"Table 2","fall","2012","Field","offshore",73.21,-135.54,"Canada Basin","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","ice","incubation at different depths","10",NA,NA,-1.2,NA,NA,27.9,NA,0.26,NA,0.26,NA,2,NA,NA,100,NA,0.049,"Carbon uptake rate (mg C/m3 h)","area-specific production","biom","dSS",NA,0.018,NA,0.005,11,NA,NA,50,NA,0.019,"Carbon uptake rate (mg C/m3 h)",1,NA,0.00771,NA,0.002,11,0.962,0.014,-2.08,0.28
"343",343,354,"222","Yun, MS; Chung, KH; Zimmermann, S; Zhao, JP; Joo, HM; Lee, SH",2012,"Phytoplankton productivity and its response to higher light levels in the Canada Basin","POLAR BIOLOGY",1,"Data in table were treated as replicates, values below 0.001 are treated as 0.001",NA,"Table 2","fall","2012","Field","offshore",73.21,-135.54,"Canada Basin","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","ice","incubation at different depths","10",NA,NA,-1.2,NA,NA,27.9,NA,0.26,NA,0.26,NA,2,NA,NA,100,NA,0.049,"Carbon uptake rate (mg C/m3 h)","area-specific production","biom","dSS",NA,0.018,NA,0.005,11,NA,NA,30,NA,0.0096,"Carbon uptake rate (mg C/m3 h)",1,NA,0.00491,NA,0.001,11,0.962,0.013,-2.871,0.369
"344",344,355,"222","Yun, MS; Chung, KH; Zimmermann, S; Zhao, JP; Joo, HM; Lee, SH",2012,"Phytoplankton productivity and its response to higher light levels in the Canada Basin","POLAR BIOLOGY",1,"Data in table were treated as replicates, values below 0.001 are treated as 0.001",NA,"Table 2","fall","2012","Field","offshore",73.21,-135.54,"Canada Basin","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","ice","incubation at different depths","10",NA,NA,-1.2,NA,NA,27.9,NA,0.26,NA,0.26,NA,2,NA,NA,100,NA,0.049,"Carbon uptake rate (mg C/m3 h)","area-specific production","biom","dSS",NA,0.018,NA,0.005,11,NA,NA,12,NA,0.0036,"Carbon uptake rate (mg C/m3 h)",1,NA,0.00229,NA,0.001,11,0.962,0.013,-3.393,0.443
"345",345,356,"222","Yun, MS; Chung, KH; Zimmermann, S; Zhao, JP; Joo, HM; Lee, SH",2012,"Phytoplankton productivity and its response to higher light levels in the Canada Basin","POLAR BIOLOGY",1,"Data in table were treated as replicates, values below 0.001 are treated as 0.001",NA,"Table 2","fall","2012","Field","offshore",73.21,-135.54,"Canada Basin","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","ice","incubation at different depths","10",NA,NA,-1.2,NA,NA,27.9,NA,0.26,NA,0.26,NA,2,NA,NA,100,NA,0.049,"Carbon uptake rate (mg C/m3 h)","area-specific production","biom","dSS",NA,0.018,NA,0.005,11,NA,NA,5,NA,0.0027,"Carbon uptake rate (mg C/m3 h)",1,NA,0.00231,NA,0.001,10,0.96,0.013,-3.371,0.461
"346",346,357,"222","Yun, MS; Chung, KH; Zimmermann, S; Zhao, JP; Joo, HM; Lee, SH",2012,"Phytoplankton productivity and its response to higher light levels in the Canada Basin","POLAR BIOLOGY",1,"Data in table were treated as replicates, values below 0.001 are treated as 0.001",NA,"Table 2","fall","2012","Field","offshore",73.21,-135.54,"Canada Basin","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","ice","incubation at different depths","10",NA,NA,-1.2,NA,NA,27.9,NA,0.26,NA,0.26,NA,2,NA,NA,100,NA,0.049,"Carbon uptake rate (mg C/m3 h)","area-specific production","biom","dSS",NA,0.018,NA,0.005,11,NA,NA,1,NA,0.0017,"Carbon uptake rate (mg C/m3 h)",1,NA,0.00116,NA,0,10,0.96,0.013,-3.462,0.476
"347",347,363,"229","Sommer, U; Lengfellner, K; Lewandowska, A",2012,"Experimental induction of a coastal spring bloom early in the year by intermittent high-light episodes","MARINE ECOLOGY PROGRESS SERIES",1,NA,"variable light intensities (steadily increasing)",NA,NA,"2012","Lab","coastal",NA,NA,"Baltic Sea","Total phytoplankton","phytoplankton",NA,"mesocosm",NA,1400,NA,"yes","herbivory","light doubling for 10 days",NA,NA,"PAR",4.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"348",348,365,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",1,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,62.422,"Chl a (mg/m2)","biomass","biom","SS",NA,6.67,NA,3.85,3,95,NA,15,NA,70.407,"Chl a (mg/m2)",2,NA,5.434,NA,3.137,3,0.8,6.083,1.05,0.759
"349",349,366,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",3,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,66.866,"Chl a (mg/m2)","biomass","biom","SS",NA,6.92,NA,3.993,3,95,NA,15,NA,87.829,"Chl a (mg/m2)",2,NA,7.903,NA,4.563,3,0.8,7.426,2.258,1.092
"350",350,367,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",6,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,61.626,"Chl a (mg/m2)","biomass","biom","SS",NA,9.63,NA,5.562,3,95,NA,15,NA,86.581,"Chl a (mg/m2)",2,NA,3.705,NA,2.139,3,0.8,7.298,2.735,1.29
"351",351,368,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",7,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,59.926,"Chl a (mg/m2)","biomass","biom","SS",NA,3.95,NA,2.282,3,95,NA,15,NA,86.165,"Chl a (mg/m2)",2,NA,4.199,NA,2.424,3,0.8,4.077,5.149,2.876
"352",352,369,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",9,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,63.087,"Chl a (mg/m2)","biomass","biom","SS",NA,3.46,NA,1.997,3,95,NA,15,NA,87.757,"Chl a (mg/m2)",2,NA,3.211,NA,1.854,3,0.8,3.337,5.914,3.582
"353",353,364,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",11,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,58.987,"Chl a (mg/m2)","biomass","biom","SS",NA,4.45,NA,2.567,3,95,NA,15,NA,54.282,"Chl a (mg/m2)",2,NA,2.717,NA,1.569,3,0.8,3.685,-1.022,0.754
"354",354,370,"232","Grinham, A; Gale, D; Udy, J",2011,"Impact of sediment type, light and nutrient availability on benthic diatom communities of a large estuarine bay: Moreton Bay, Australia","JOURNAL OF PALEOLIMNOLOGY",1,"it is not clear on which site manipulative experiment was performed; not clear if for chl-a concentrations standard error or standard deviation is given",NA,"Fig 4","summer","2011","Field","coastal",-27.29,153.32,"Moreton Bay, Australia","Total phytobenthos","phytobenthos",11,"field plot","no container",NA,NA,"yes","none","shading screen","natural",2109,"PAR",26.1,NA,NA,35.4,NA,NA,NA,9.28,NA,1,632,NA,100,NA,58.975,"Chl a (mg/m2)","biomass","biom","SS",NA,5.43,NA,3.137,3,95,NA,15,NA,86.64,"Chl a (mg/m2)",2,NA,8.892,NA,5.134,3,0.8,7.368,3.004,1.418
"355",355,371,"234","Mette, EM; Vanni, MJ; Newell, JM; Gonzalez, MJ",2011,"Phytoplankton communities and stoichiometry are interactively affected by light, nutrients, and fish","LIMNOLOGY AND OCEANOGRAPHY",1,NA,"Freshwater",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"356",356,372,"236","Petrou, K; Hassler, CS; Doblin, MA; Shelly, K; Schoemann, V; van den Enden, R; Wright, S; Ralph, PJ",2011,"Iron-limitation and high light stress on phytoplankton populations from the Australian Sub-Antarctic Zone (SAZ)","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,NA,"not clear if the cells are cultured or only measured under different light conditions",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"357",357,373,"239","Rubach, A; Hillebrand, H; Eriksson, BK",2011,"Understorey benthic microalgae and their consumers depend on habitat complexity and light in a microtidal coastal ecosystem","AQUATIC BOTANY",1,NA,NA,"Fig 1","fall","2011","Field","coastal",54.41,10,"Schlei Fjord, Baltic Sea","Total phytobenthos","phytobenthos",120,"field plot","no container",NA,NA,"yes","none","shading screen","natural",NA,NA,NA,NA,NA,16,0.77,2.28,0.77,2.28,NA,4,NA,NA,100,NA,0.136,"biovolume (mm3 cm-2)","biomass","biom","SS",NA,0.017,NA,0.01,3,NA,NA,50,NA,0.07,"biovolume (mm3 cm-2)",2,NA,0.047,NA,0.027,3,0.8,0.036,-1.49,0.852
"358",358,374,"239","Rubach, A; Hillebrand, H; Eriksson, BK",2011,"Understorey benthic microalgae and their consumers depend on habitat complexity and light in a microtidal coastal ecosystem","AQUATIC BOTANY",1,NA,NA,"Fig 1","fall","2011","Field","coastal",54.41,10,"Schlei Fjord, Baltic Sea","Total phytobenthos","phytobenthos",120,"field plot","no container",NA,NA,"yes","none","shading screen","natural",NA,NA,NA,NA,NA,16,0.77,2.28,0.77,2.28,NA,4,NA,NA,100,NA,0.25,"biovolume (mm3 cm-2)","biomass","biom","SS",NA,0.025,NA,0.014,3,NA,NA,50,NA,0.125,"biovolume (mm3 cm-2)",2,NA,0.066,NA,0.038,3,0.8,0.05,-2,1
"359",359,375,"241","Rothausler, E; Gomez, I; Karsten, U; Tala, F; Thiel, M",2011,"Physiological acclimation of floating Macrocystis pyrifera to temperature and irradiance ensures long-term persistence at the sea surface at mid-latitudes","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"macroalgae","No change in light intensity, only addition of UV radiation",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"360",360,376,"243","Russell, BD; Passarelli, CA; Connell, SD",2011,"FORECASTED CO2 MODIFIES THE INFLUENCE OF LIGHT IN SHAPING SUBTIDAL HABITAT","JOURNAL OF PHYCOLOGY",1,"macroalgae",NA,"Fig 2","spring","2011","Field","coastal",-35.57,138.63,"Victor Harbour, South Australia","Lithophyllum sp.","macroalgae",50,"mesocosm","Aquaria",40,NA,"unknown","none","shading screen","natural",NA,NA,NA,8.1,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,10.114,"dry weight (mg)","biomass","biom","SS",NA,4.09,NA,1.827,5,NA,NA,10,NA,17.357,"dry weight (mg)",2,NA,4.377,NA,1.958,5,0.903,4.234,1.545,0.519
"361",361,377,"243","Russell, BD; Passarelli, CA; Connell, SD",2011,"FORECASTED CO2 MODIFIES THE INFLUENCE OF LIGHT IN SHAPING SUBTIDAL HABITAT","JOURNAL OF PHYCOLOGY",1,"macroalgae",NA,"Fig 2","spring","2011","Field","coastal",-35.57,138.63,"Victor Harbour, South Australia","Lithophyllum sp.","macroalgae",50,"mesocosm","Aquaria",40,NA,"unknown","none","shading screen","natural",NA,NA,NA,8.1,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.516,"relative electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,1.03,NA,0.463,5,NA,NA,10,NA,5.384,"relative electron transport rate (µmol e m-2 s-1)",1,NA,1.247,NA,0.558,5,0.903,1.146,1.473,0.508
"362",362,378,"243","Russell, BD; Passarelli, CA; Connell, SD",2011,"FORECASTED CO2 MODIFIES THE INFLUENCE OF LIGHT IN SHAPING SUBTIDAL HABITAT","JOURNAL OF PHYCOLOGY",1,"macroalgae",NA,"Fig 3","spring","2011","Field","coastal",-35.57,138.63,"Victor Harbour, South Australia","Feldmannia sp.","macroalgae",50,"mesocosm","Aquaria",40,NA,"unknown","none","shading screen","natural",NA,NA,NA,8.1,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,42.427,"dry weight (mg)","biomass","biom","SS",NA,12.38,NA,5.537,5,NA,NA,10,NA,19.951,"dry weight (mg)",2,NA,6.555,NA,2.932,5,0.903,9.907,-2.049,0.61
"363",363,379,"243","Russell, BD; Passarelli, CA; Connell, SD",2011,"FORECASTED CO2 MODIFIES THE INFLUENCE OF LIGHT IN SHAPING SUBTIDAL HABITAT","JOURNAL OF PHYCOLOGY",1,"macroalgae",NA,"Fig 3","spring","2011","Field","coastal",-35.57,138.63,"Victor Harbour, South Australia","Feldmannia sp.","macroalgae",50,"mesocosm","Aquaria",40,NA,"unknown","none","shading screen","natural",NA,NA,NA,8.1,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,7.358,"relative electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,0.85,NA,0.38,5,NA,NA,10,NA,4.068,"relative electron transport rate (µmol e m-2 s-1)",1,NA,0.85,NA,0.38,5,0.903,0.85,-3.496,1.011
"364",364,380,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,820,NA,82,NA,0.088,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.007,NA,0.004,3,0.8,0.007,1.114,0.77
"365",365,381,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,720,NA,72,NA,0.068,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.009,NA,0.005,3,0.8,0.008,-1.007,0.751
"366",366,382,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,520,NA,52,NA,0.065,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.009,NA,0.005,3,0.8,0.009,-1.235,0.794
"367",367,383,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,410,NA,41,NA,0.046,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.004,NA,0.002,3,0.8,0.006,-4.257,2.177
"368",368,384,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,320,NA,32,NA,0.032,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.003,NA,0.002,3,0.8,0.006,-6.406,4.086
"369",369,385,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,230,NA,23,NA,0.027,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.009,NA,0.005,3,0.8,0.008,-4.897,2.665
"370",370,386,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,120,NA,12,NA,0.019,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.014,NA,0.008,3,0.8,0.012,-4.106,2.072
"371",371,387,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.078,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,60,NA,6,NA,0.016,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.014,NA,0.008,3,0.8,0.012,-4.299,2.207
"372",372,388,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,820,NA,82,NA,215.447,"relative electron transport rate (light curve)",1,NA,16.26,NA,9.388,3,0.8,32.029,-1.178,0.782
"373",373,389,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,720,NA,72,NA,215.447,"relative electron transport rate (light curve)",1,NA,16.26,NA,9.388,3,0.8,32.029,-1.178,0.782
"374",374,390,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,520,NA,52,NA,167.48,"relative electron transport rate (light curve)",1,NA,21.951,NA,12.674,3,0.8,33.683,-2.259,1.092
"375",375,391,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,410,NA,41,NA,153.659,"relative electron transport rate (light curve)",1,NA,13.008,NA,7.51,3,0.8,31.277,-2.787,1.314
"376",376,392,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,320,NA,32,NA,75.61,"relative electron transport rate (light curve)",1,NA,11.382,NA,6.571,3,0.8,30.958,-4.832,2.612
"377",377,393,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,230,NA,23,NA,80.488,"relative electron transport rate (light curve)",1,NA,9.756,NA,5.633,3,0.8,30.68,-4.749,2.546
"378",378,394,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,120,NA,12,NA,43.902,"relative electron transport rate (light curve)",1,NA,10.569,NA,6.102,3,0.8,30.814,-5.678,3.353
"379",379,395,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza early stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,262.602,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,42.276,NA,24.408,3,60,NA,6,NA,31.707,"relative electron transport rate (light curve)",1,NA,8.13,NA,4.694,3,0.8,30.442,-6.068,3.735
"380",380,396,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,820,NA,82,NA,0.061,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.005,NA,0.003,3,0.8,0.006,4,2
"381",381,397,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,720,NA,72,NA,0.052,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.004,NA,0.002,3,0.8,0.006,3.163,1.5
"382",382,398,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,520,NA,52,NA,0.045,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.012,NA,0.007,3,0.8,0.01,1.284,0.804
"383",383,399,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,410,NA,41,NA,0.035,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.007,NA,0.004,3,0.8,0.007,0.749,0.713
"384",384,400,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,320,NA,32,NA,0.032,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.003,NA,0.002,3,0.8,0.006,0.473,0.685
"385",385,401,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,230,NA,23,NA,0.04,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.011,NA,0.006,3,0.8,0.009,0.94,0.74
"386",386,402,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,120,NA,12,NA,0.027,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.006,NA,0.003,3,0.8,0.007,-0.178,0.669
"387",387,403,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 4B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,0.029,"Photosynthesis (µmol O2 mg chla-1 s-1)","mass-specific production","phys","dQ",NA,0.008,NA,0.004,3,60,NA,6,NA,0.021,"Photosynthesis (µmol O2 mg chla-1 s-1)",1,NA,0.002,NA,0.001,3,0.8,0.006,-1.137,0.774
"388",388,404,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,820,NA,82,NA,295.122,"relative electron transport rate (light curve)",1,NA,34.146,NA,19.714,3,0.8,39.328,1.224,0.791
"389",389,405,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,720,NA,72,NA,270.732,"relative electron transport rate (light curve)",1,NA,8.13,NA,4.694,3,0.8,31.572,0.906,0.735
"390",390,406,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,520,NA,52,NA,187.805,"relative electron transport rate (light curve)",1,NA,3.252,NA,1.878,3,0.8,31.129,-1.212,0.789
"391",391,407,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,410,NA,41,NA,191.057,"relative electron transport rate (light curve)",1,NA,8.13,NA,4.694,3,0.8,31.572,-1.112,0.77
"392",392,408,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,320,NA,32,NA,129.268,"relative electron transport rate (light curve)",1,NA,14.634,NA,8.449,3,0.8,32.723,-2.584,1.223
"393",393,409,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,230,NA,23,NA,88.618,"relative electron transport rate (light curve)",1,NA,9.756,NA,5.633,3,0.8,31.801,-3.681,1.796
"394",394,410,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,120,NA,12,NA,58.537,"relative electron transport rate (light curve)",1,NA,5.691,NA,3.286,3,0.8,31.303,-4.509,2.361
"395",395,411,"246","Kim, JH; Kang, EJ; Park, MG; Lee, BG; Kim, KY",2011,"Effects of temperature and irradiance on photosynthesis and growth of a green-tide-forming species (Ulva linza) in the Yellow Sea","JOURNAL OF APPLIED PHYCOLOGY",1,"macroalgae",NA,"Fig 5B",NA,"2011","Lab","coastal",34.61,125.75,"Yellow Sea","Ulva linza late stage","macroalgae",7,"microcosm","Bottle",0.5,NA,"unknown","none","reduced light","16",NA,NA,20,NA,NA,32,NA,NA,NA,NA,NA,0,1000,NA,100,NA,234.959,"relative electron transport rate (light curve)","quantum yield","phys","dQ",NA,43.902,NA,25.347,3,60,NA,6,NA,39.837,"relative electron transport rate (light curve)",1,NA,1.626,NA,0.939,3,0.8,31.065,-5.025,2.771
"396",396,412,"249","Ihnken, S; Roberts, S; Beardall, J",2011,"Differential responses of growth and photosynthesis in the marine diatom Chaetoceros muelleri to CO2 and light availability","PHYCOLOGIA",1,NA,"only minimum number of replicates is given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"397",397,413,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,21.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,257.374,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,153.78,NA,68.774,5,NA,NA,16,NA,110.401,"Leaf Biomass (g dw/m2)",2,NA,48.453,NA,21.669,5,0.903,114.011,-1.164,0.468
"398",398,414,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,21.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,257.374,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,153.78,NA,68.774,5,NA,NA,8,NA,70.833,"Leaf Biomass (g dw/m2)",2,NA,40.026,NA,17.9,5,0.903,112.364,-1.499,0.512
"399",399,419,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,18.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,209.324,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,50.56,NA,22.612,5,NA,NA,16,NA,207.911,"Leaf Biomass (g dw/m2)",2,NA,87.428,NA,39.099,5,0.903,71.415,-0.018,0.4
"400",400,420,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,18.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,209.324,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,50.56,NA,22.612,5,NA,NA,8,NA,70.831,"Leaf Biomass (g dw/m2)",2,NA,21.069,NA,9.422,5,0.903,38.732,-3.23,0.922
"401",401,425,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,21.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,176.376,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,111.65,NA,49.933,5,NA,NA,16,NA,133.289,"Stem Biomass (g dw/m2)",2,NA,51.325,NA,22.953,5,0.903,86.893,-0.448,0.41
"402",402,426,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,21.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,176.376,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,111.65,NA,49.933,5,NA,NA,8,NA,118.389,"Stem Biomass (g dw/m2)",2,NA,54.026,NA,24.161,5,0.903,87.708,-0.597,0.418
"403",403,431,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,18.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,174.362,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,87.34,NA,39.06,5,NA,NA,16,NA,207.785,"Stem Biomass (g dw/m2)",2,NA,46.822,NA,20.94,5,0.903,70.075,0.431,0.409
"404",404,432,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 2","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",90,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,18.7,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,174.362,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,87.34,NA,39.06,5,NA,NA,8,NA,83.356,"Stem Biomass (g dw/m2)",2,NA,15.307,NA,6.846,5,0.903,62.701,-1.311,0.486
"405",405,415,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,222.586,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,73.48,NA,32.86,5,NA,NA,16,NA,38.564,"Leaf Biomass (g dw/m2)",2,NA,14.697,NA,6.573,5,0.903,52.986,-3.137,0.892
"406",406,416,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,222.586,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,73.48,NA,32.86,5,NA,NA,8,NA,7.637,"Leaf Biomass (g dw/m2)",2,NA,19.018,NA,8.505,5,0.903,53.669,-3.617,1.054
"407",407,421,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,175.034,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,85.58,NA,38.273,5,NA,NA,16,NA,32.765,"Leaf Biomass (g dw/m2)",2,NA,5.187,NA,2.32,5,0.903,60.626,-2.12,0.625
"408",408,422,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,175.034,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,85.58,NA,38.273,5,NA,NA,8,NA,8.41,"Leaf Biomass (g dw/m2)",2,NA,13.832,NA,6.186,5,0.903,61.301,-2.455,0.701
"409",409,427,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,176.973,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,36.45,NA,16.303,5,NA,NA,16,NA,176.976,"Stem Biomass (g dw/m2)",2,NA,80.707,NA,36.093,5,0.903,62.62,0,0.4
"410",410,428,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,176.973,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,36.45,NA,16.303,5,NA,NA,8,NA,87.715,"Stem Biomass (g dw/m2)",2,NA,46.859,NA,20.956,5,0.903,41.98,-1.92,0.584
"411",411,433,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,157.18,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,61.61,NA,27.555,5,NA,NA,16,NA,101.683,"Stem Biomass (g dw/m2)",2,NA,10.41,NA,4.656,5,0.903,44.186,-1.134,0.464
"412",412,434,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 6","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",180,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,157.18,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,61.61,NA,27.555,5,NA,NA,8,NA,118.761,"Stem Biomass (g dw/m2)",2,NA,27.763,NA,12.416,5,0.903,47.787,-0.726,0.426
"413",413,417,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.6,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,214.471,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,39.71,NA,17.761,5,NA,NA,16,NA,0.979,"Leaf Biomass (g dw/m2)",2,NA,4.413,NA,1.974,5,0.903,28.255,-6.825,2.729
"414",414,418,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.6,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,214.471,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,39.71,NA,17.761,5,NA,NA,8,NA,1.637,"Leaf Biomass (g dw/m2)",2,NA,2.942,NA,1.316,5,0.903,28.159,-6.827,2.73
"415",415,423,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.8,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,191.104,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,38.13,NA,17.054,5,NA,NA,16,NA,14.733,"Leaf Biomass (g dw/m2)",2,NA,6.171,NA,2.76,5,0.903,27.316,-5.832,2.1
"416",416,424,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.8,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,191.104,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,38.13,NA,17.054,5,NA,NA,8,NA,2.295,"Leaf Biomass (g dw/m2)",2,NA,5.149,NA,2.303,5,0.903,27.21,-6.267,2.364
"417",417,429,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.6,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,197.497,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,63.71,NA,28.49,5,NA,NA,16,NA,143.671,"Stem Biomass (g dw/m2)",2,NA,46.019,NA,20.58,5,0.903,55.57,-0.875,0.438
"418",418,430,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.6,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,197.497,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,63.71,NA,28.49,5,NA,NA,8,NA,91.428,"Stem Biomass (g dw/m2)",2,NA,47.789,NA,21.372,5,0.903,56.312,-1.701,0.545
"419",419,435,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.8,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,184.043,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,33.63,NA,15.04,5,NA,NA,16,NA,113.588,"Stem Biomass (g dw/m2)",2,NA,31.874,NA,14.254,5,0.903,32.763,-1.942,0.589
"420",420,436,"252","McMahon, K; Lavery, PS; Mulligan, M",2011,"Recovery from the impact of light reduction on the seagrass Amphibolis griffithii, insights for dredging management","MARINE POLLUTION BULLETIN",1,"seagrass",NA,"Fig 7","fall","2011","Field","coastal",-30,115,"Jurien Bay, Western Australian","Amphibolis griffithii","seagrass",270,"field plot","no container",NA,NA,"unknown","interval","shading screen","natural",NA,NA,19.8,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,184.043,"Stem Biomass (g dw/m2)","biomass","biom","SS",NA,33.63,NA,15.04,5,NA,NA,8,NA,104.485,"Stem Biomass (g dw/m2)",2,NA,58.423,NA,26.128,5,0.903,47.667,-1.508,0.514
"421",421,437,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",16,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.54,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.34,NA,0.098,12,NA,NA,20,NA,1.479,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.55,NA,0.159,12,0.966,0.456,-0.129,0.167
"422",422,443,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",16,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.54,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.34,NA,0.098,12,NA,NA,10,NA,1.284,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.042,NA,0.012,12,0.966,0.241,-1.027,0.189
"423",423,449,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",16,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.54,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.34,NA,0.098,12,NA,NA,1,NA,1.052,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.423,NA,0.122,12,0.966,0.383,-1.231,0.198
"424",424,438,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",33,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,2.075,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.59,NA,0.171,12,NA,NA,20,NA,1.843,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.381,NA,0.11,12,0.966,0.498,-0.45,0.171
"425",425,444,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",33,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,2.075,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.59,NA,0.171,12,NA,NA,10,NA,2.075,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.592,NA,0.171,12,0.966,0.592,0,0.167
"426",426,450,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",33,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,2.075,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.59,NA,0.171,12,NA,NA,1,NA,1.343,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.592,NA,0.171,12,0.966,0.592,-1.195,0.196
"427",427,439,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",43,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,2.465,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.68,NA,0.195,12,NA,NA,20,NA,2.111,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.55,NA,0.159,12,0.966,0.616,-0.555,0.173
"428",428,445,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",43,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,2.465,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.68,NA,0.195,12,NA,NA,10,NA,1.806,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.508,NA,0.147,12,0.966,0.598,-1.064,0.19
"429",429,451,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",43,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,2.465,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.68,NA,0.195,12,NA,NA,1,NA,0.914,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.888,NA,0.256,12,0.966,0.79,-1.896,0.242
"430",430,440,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",57,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.465,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,2.24,NA,0.647,12,NA,NA,20,NA,2.158,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.55,NA,0.159,12,0.966,1.632,-0.773,0.179
"431",431,446,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",57,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.465,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,2.24,NA,0.647,12,NA,NA,10,NA,1.682,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.423,NA,0.122,12,0.966,1.613,-1.067,0.19
"432",432,452,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",57,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.465,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,2.24,NA,0.647,12,NA,NA,1,NA,1.719,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.381,NA,0.11,12,0.966,1.608,-1.048,0.19
"433",433,441,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",91,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.107,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,1.02,NA,0.293,12,NA,NA,20,NA,3.095,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.931,NA,0.269,12,0.966,0.974,-0.012,0.167
"434",434,447,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",91,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.107,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,1.02,NA,0.293,12,NA,NA,10,NA,2.203,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.719,NA,0.208,12,0.966,0.88,-0.992,0.187
"435",435,453,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",91,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.107,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,1.02,NA,0.293,12,NA,NA,1,NA,1.312,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.931,NA,0.269,12,0.966,0.974,-1.78,0.233
"436",436,442,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.092,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.97,NA,0.281,12,NA,NA,20,NA,3.666,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,1.057,NA,0.305,12,0.966,1.016,0.545,0.173
"437",437,448,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.092,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.97,NA,0.281,12,NA,NA,10,NA,2.042,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.761,NA,0.22,12,0.966,0.873,-1.161,0.195
"438",438,454,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 3","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,3.092,"Net leaf production (mg dryweight day-1 shoot-1)","mass-specific production","phys","dQ",NA,0.97,NA,0.281,12,NA,NA,1,NA,0.479,"Net leaf production (mg dryweight day-1 shoot-1)",2,NA,0.423,NA,0.122,12,0.966,0.75,-3.363,0.402
"439",439,455,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 5A","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,481.333,"shoots/m2","abundance","biom","SS",NA,84.37,NA,24.355,12,NA,NA,20,NA,539.451,"shoots/m2",2,NA,275.352,NA,79.487,12,0.966,203.638,0.276,0.168
"440",440,456,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 5A","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,481.333,"shoots/m2","abundance","biom","SS",NA,84.37,NA,24.355,12,NA,NA,10,NA,471.928,"shoots/m2",2,NA,150.986,NA,43.586,12,0.966,122.3,-0.074,0.167
"441",441,457,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 5A","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,481.333,"shoots/m2","abundance","biom","SS",NA,84.37,NA,24.355,12,NA,NA,1,NA,408.24,"shoots/m2",2,NA,150.999,NA,43.59,12,0.966,122.309,-0.577,0.174
"442",442,458,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 5B","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,59.799,"Cover (%)","biomass","biom","SS",NA,18.04,NA,5.209,12,NA,NA,20,NA,44.344,"Cover (%)",2,NA,17.153,NA,4.952,12,0.966,17.604,-0.848,0.182
"443",443,459,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 5B","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,59.799,"Cover (%)","biomass","biom","SS",NA,18.04,NA,5.209,12,NA,NA,10,NA,54.74,"Cover (%)",2,NA,10.694,NA,3.087,12,0.966,14.831,-0.329,0.169
"444",444,460,"256","Serrano, O; Mateo, MA; Renom, P",2011,"Seasonal response of Posidonia oceanica to light disturbances","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass; only spring data were evaluated, because autumn data were not readily visible in the plots",NA,"Fig 5B","spring-summer","2011","Field","coastal",42.3,3.29,"Portlligat Bay, Mediterranean Sea","Posidonia oceanica","seagrass",119,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,59.799,"Cover (%)","biomass","biom","SS",NA,18.04,NA,5.209,12,NA,NA,1,NA,27.194,"Cover (%)",2,NA,24.059,NA,6.945,12,0.966,21.265,-1.48,0.212
"445",445,461,"268","Becker, S; Graeve, M; Bischof, K",2010,"Photosynthesis and lipid composition of the Antarctic endemic rhodophyte Palmaria decipiens: effects of changing light and temperature levels","POLAR BIOLOGY",1,"macroalgae","light regimes were not entirely clear; also only photosynthetic parameters",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"446",446,462,"277","Martinez, R; Orive, E; Laza-Martinez, A; Seoane, S",2010,"Growth response of six strains of Heterosigma akashiwo to varying temperature, salinity and irradiance conditions","JOURNAL OF PLANKTON RESEARCH",1,"Number of replicates are given, but no standard deviation; thus, data from the different strains were treated as replicates (n=6)",NA,"Table 2",NA,"2010","Lab","coastal",NA,NA,NA,"Heterosigma akashiwo","phytoplankton",10,"microcosm","test tube",NA,NA,"no","none","reduced light","12",NA,NA,17,NA,NA,20,36.3,882,36.3,882,107,5,100,NA,100,NA,0.317,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.045,NA,0.018,6,40,NA,40,NA,0.305,"Growth rate (µ/d)",2,NA,0.078,NA,0.032,6,0.923,0.063,-0.165,0.334
"447",447,463,"277","Martinez, R; Orive, E; Laza-Martinez, A; Seoane, S",2010,"Growth response of six strains of Heterosigma akashiwo to varying temperature, salinity and irradiance conditions","JOURNAL OF PLANKTON RESEARCH",1,"Number of replicates are given, but no standard deviation; thus, data from the different strains were treated as replicates (n=6)",NA,"Table 2",NA,"2010","Lab","coastal",NA,NA,NA,"Heterosigma akashiwo","phytoplankton",10,"microcosm","test tube",NA,NA,"no","none","reduced light","12",NA,NA,17,NA,NA,35,36.3,882,36.3,882,107,5,100,NA,100,NA,0.339,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.083,NA,0.034,6,40,NA,40,NA,0.349,"Growth rate (µ/d)",2,NA,0.087,NA,0.035,6,0.923,0.085,0.116,0.334
"448",448,464,"277","Martinez, R; Orive, E; Laza-Martinez, A; Seoane, S",2010,"Growth response of six strains of Heterosigma akashiwo to varying temperature, salinity and irradiance conditions","JOURNAL OF PLANKTON RESEARCH",1,"Number of replicates are given, but no standard deviation; thus, data from the different strains were treated as replicates (n=6)",NA,"Table 2",NA,"2010","Lab","coastal",NA,NA,NA,"Heterosigma akashiwo","phytoplankton",10,"microcosm","test tube",NA,NA,"no","none","reduced light","12",NA,NA,23,NA,NA,20,36.3,882,36.3,882,107,5,100,NA,100,NA,0.421,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.057,NA,0.023,6,40,NA,40,NA,0.289,"Growth rate (µ/d)",2,NA,0.025,NA,0.01,6,0.923,0.044,-2.774,0.654
"449",449,465,"277","Martinez, R; Orive, E; Laza-Martinez, A; Seoane, S",2010,"Growth response of six strains of Heterosigma akashiwo to varying temperature, salinity and irradiance conditions","JOURNAL OF PLANKTON RESEARCH",1,"Number of replicates are given, but no standard deviation; thus, data from the different strains were treated as replicates (n=6)",NA,"Table 2",NA,"2010","Lab","coastal",NA,NA,NA,"Heterosigma akashiwo","phytoplankton",10,"microcosm","test tube",NA,NA,"no","none","reduced light","12",NA,NA,23,NA,NA,35,36.3,882,36.3,882,107,5,100,NA,100,NA,0.475,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.057,NA,0.023,6,40,NA,40,NA,0.344,"Growth rate (µ/d)",2,NA,0.087,NA,0.036,6,0.923,0.074,-1.647,0.446
"450",450,466,"279","Feng, Y; Hare, CE; Rose, JM; Handy, SM; DiTullio, GR; Lee, PA; Smith, WO; Peloquin, J; Tozzi, S; Sun, J; Zhang, Y; Dunbar, RB; Long, MC; Sohst, B; Lohan, M; Hutchins, DA",2010,"Interactive effects of iron, irradiance and CO2 on Ross Sea phytoplankton","DEEP-SEA RESEARCH PART I-OCEANOGRAPHIC RESEARCH PAPERS",1,NA,"variable light intensities over the incubation",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"451",451,467,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.401,"Chl a (µg/L)","biomass","biom","SS",NA,0.008,NA,0.005,3,NA,NA,40,NA,0.354,"Chl a (µg/L)",2,NA,0.014,NA,0.008,3,0.8,0.012,-3.263,1.554
"452",452,468,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.54,"Chl a (µg/L)","biomass","biom","SS",NA,0.031,NA,0.018,3,NA,NA,40,NA,0.431,"Chl a (µg/L)",2,NA,0.041,NA,0.023,3,0.8,0.036,-2.402,1.148
"453",453,469,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.372,"Chl a (µg/L)","biomass","biom","SS",NA,0.045,NA,0.026,3,NA,NA,40,NA,0.329,"Chl a (µg/L)",2,NA,0.027,NA,0.016,3,0.8,0.037,-0.944,0.741
"454",454,470,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.52,"Chl a (µg/L)","biomass","biom","SS",NA,0.031,NA,0.018,3,NA,NA,40,NA,0.263,"Chl a (µg/L)",2,NA,0.022,NA,0.013,3,0.8,0.027,-7.646,5.538
"455",455,471,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.286,"Chl a (µg/L)","biomass","biom","SS",NA,0.023,NA,0.013,3,NA,NA,40,NA,0.272,"Chl a (µg/L)",2,NA,0.014,NA,0.008,3,0.8,0.019,-0.6,0.697
"456",456,472,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.175,"Chl a (µg/L)","biomass","biom","SS",NA,0.017,NA,0.01,3,NA,NA,40,NA,0.22,"Chl a (µg/L)",2,NA,0.021,NA,0.012,3,0.8,0.019,1.888,0.964
"457",457,497,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.517,"Fv/Fm","quantum yield","phys","dQ",NA,0.008,NA,0.005,3,NA,NA,40,NA,0.536,"Fv/Fm",1,NA,0.02,NA,0.012,3,0.8,0.015,0.945,0.741
"458",458,498,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.477,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.521,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.01,3.452,1.659
"459",459,499,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.444,"Fv/Fm","quantum yield","phys","dQ",NA,0.016,NA,0.009,3,NA,NA,40,NA,0.486,"Fv/Fm",1,NA,0.026,NA,0.015,3,0.8,0.022,1.556,0.868
"460",460,500,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.439,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.477,"Fv/Fm",1,NA,0.018,NA,0.01,3,0.8,0.015,1.987,0.996
"461",461,501,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.438,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.289,"Fv/Fm",1,NA,0.004,NA,0.002,3,0.8,0.005,-23.211,45.563
"462",462,502,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.458,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.466,"Fv/Fm",1,NA,0.006,NA,0.003,3,0.8,0.009,0.674,0.705
"463",463,527,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.414,"Chl a (µg/L)","biomass","biom","SS",NA,0.005,NA,0.003,3,NA,NA,40,NA,0.351,"Chl a (µg/L)",2,NA,0.017,NA,0.01,3,0.8,0.012,-4.074,2.05
"464",464,528,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.431,"Chl a (µg/L)","biomass","biom","SS",NA,0.035,NA,0.02,3,NA,NA,40,NA,0.352,"Chl a (µg/L)",2,NA,0.114,NA,0.066,3,0.8,0.085,-0.747,0.713
"465",465,529,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.322,"Chl a (µg/L)","biomass","biom","SS",NA,0.03,NA,0.018,3,NA,NA,40,NA,0.269,"Chl a (µg/L)",2,NA,0.042,NA,0.025,3,0.8,0.037,-1.152,0.777
"466",466,530,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.339,"Chl a (µg/L)","biomass","biom","SS",NA,0.074,NA,0.042,3,NA,NA,40,NA,0.214,"Chl a (µg/L)",2,NA,0.029,NA,0.017,3,0.8,0.056,-1.796,0.935
"467",467,531,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.32,"Chl a (µg/L)","biomass","biom","SS",NA,0.021,NA,0.012,3,NA,NA,40,NA,0.233,"Chl a (µg/L)",2,NA,0.022,NA,0.012,3,0.8,0.021,-3.267,1.556
"468",468,532,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.167,"Chl a (µg/L)","biomass","biom","SS",NA,0.01,NA,0.006,3,NA,NA,40,NA,0.205,"Chl a (µg/L)",2,NA,0.015,NA,0.008,3,0.8,0.013,2.457,1.17
"469",469,557,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.523,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.54,"Fv/Fm",1,NA,0.022,NA,0.013,3,0.8,0.018,0.722,0.71
"470",470,558,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.433,"Fv/Fm","quantum yield","phys","dQ",NA,0.026,NA,0.015,3,NA,NA,40,NA,0.519,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.019,3.577,1.733
"471",471,559,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.421,"Fv/Fm","quantum yield","phys","dQ",NA,0.119,NA,0.069,3,NA,NA,40,NA,0.446,"Fv/Fm",1,NA,0.068,NA,0.04,3,0.8,0.097,0.199,0.67
"472",472,560,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.33,"Fv/Fm","quantum yield","phys","dQ",NA,0.03,NA,0.017,3,NA,NA,40,NA,0.404,"Fv/Fm",1,NA,0.042,NA,0.024,3,0.8,0.037,1.622,0.886
"473",473,561,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.418,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.281,"Fv/Fm",1,NA,0.118,NA,0.068,3,0.8,0.084,-1.297,0.807
"474",474,562,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",1,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.45,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.006,3,NA,NA,40,NA,0.462,"Fv/Fm",1,NA,0.024,NA,0.014,3,0.8,0.018,0.522,0.689
"475",475,473,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.528,"Chl a (µg/L)","biomass","biom","SS",NA,0.036,NA,0.021,3,NA,NA,40,NA,0.349,"Chl a (µg/L)",2,NA,0.021,NA,0.012,3,0.8,0.03,-4.856,2.632
"476",476,474,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.692,"Chl a (µg/L)","biomass","biom","SS",NA,0.032,NA,0.018,3,NA,NA,40,NA,0.467,"Chl a (µg/L)",2,NA,0.202,NA,0.117,3,0.8,0.145,-1.244,0.796
"477",477,475,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.659,"Chl a (µg/L)","biomass","biom","SS",NA,0.054,NA,0.031,3,NA,NA,40,NA,0.279,"Chl a (µg/L)",2,NA,0.1,NA,0.057,3,0.8,0.08,-3.787,1.862
"478",478,476,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.625,"Chl a (µg/L)","biomass","biom","SS",NA,0.127,NA,0.073,3,NA,NA,40,NA,0.224,"Chl a (µg/L)",2,NA,0.052,NA,0.03,3,0.8,0.097,-3.316,1.583
"479",479,477,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.595,"Chl a (µg/L)","biomass","biom","SS",NA,0.039,NA,0.022,3,NA,NA,40,NA,0.108,"Chl a (µg/L)",2,NA,0.028,NA,0.016,3,0.8,0.034,-11.568,11.818
"480",480,478,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.575,"Chl a (µg/L)","biomass","biom","SS",NA,0.041,NA,0.024,3,NA,NA,40,NA,0.363,"Chl a (µg/L)",2,NA,0.181,NA,0.104,3,0.8,0.131,-1.3,0.807
"481",481,503,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.515,"Fv/Fm","quantum yield","phys","dQ",NA,0.018,NA,0.01,3,NA,NA,40,NA,0.536,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.014,1.149,0.777
"482",482,504,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.491,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.006,3,NA,NA,40,NA,0.475,"Fv/Fm",1,NA,0.128,NA,0.074,3,0.8,0.091,-0.142,0.668
"483",483,505,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.473,"Fv/Fm","quantum yield","phys","dQ",NA,0.028,NA,0.016,3,NA,NA,40,NA,0.501,"Fv/Fm",1,NA,0.018,NA,0.01,3,0.8,0.024,0.952,0.742
"484",484,506,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.371,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.473,"Fv/Fm",1,NA,0.012,NA,0.007,3,0.8,0.012,6.799,4.518
"485",485,507,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.5,"Fv/Fm","quantum yield","phys","dQ",NA,0.004,NA,0.002,3,NA,NA,40,NA,0.456,"Fv/Fm",1,NA,0.048,NA,0.028,3,0.8,0.034,-1.033,0.756
"486",486,508,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.489,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.519,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.007,3.392,1.625
"487",487,533,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.504,"Chl a (µg/L)","biomass","biom","SS",NA,0.007,NA,0.004,3,NA,NA,40,NA,0.349,"Chl a (µg/L)",2,NA,0.019,NA,0.011,3,0.8,0.014,-8.79,7.106
"488",488,534,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.598,"Chl a (µg/L)","biomass","biom","SS",NA,0.056,NA,0.032,3,NA,NA,40,NA,0.546,"Chl a (µg/L)",2,NA,0.045,NA,0.026,3,0.8,0.051,-0.809,0.721
"489",489,535,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.55,"Chl a (µg/L)","biomass","biom","SS",NA,0.155,NA,0.089,3,NA,NA,40,NA,0.354,"Chl a (µg/L)",2,NA,0.029,NA,0.017,3,0.8,0.112,-1.405,0.831
"490",490,536,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.316,"Chl a (µg/L)","biomass","biom","SS",NA,0.073,NA,0.042,3,NA,NA,40,NA,0.229,"Chl a (µg/L)",2,NA,0.066,NA,0.038,3,0.8,0.07,-1.003,0.75
"491",491,537,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.462,"Chl a (µg/L)","biomass","biom","SS",NA,0.062,NA,0.036,3,NA,NA,40,NA,0.164,"Chl a (µg/L)",2,NA,0.039,NA,0.023,3,0.8,0.052,-4.581,2.416
"492",492,538,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.426,"Chl a (µg/L)","biomass","biom","SS",NA,0.19,NA,0.11,3,NA,NA,40,NA,0.11,"Chl a (µg/L)",2,NA,0.005,NA,0.003,3,0.8,0.135,-1.875,0.96
"493",493,563,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.521,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.55,"Fv/Fm",1,NA,0.012,NA,0.007,3,0.8,0.012,1.867,0.957
"494",494,564,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.465,"Fv/Fm","quantum yield","phys","dQ",NA,0.026,NA,0.015,3,NA,NA,40,NA,0.523,"Fv/Fm",1,NA,0.016,NA,0.009,3,0.8,0.022,2.149,1.052
"495",495,565,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.439,"Fv/Fm","quantum yield","phys","dQ",NA,0.032,NA,0.019,3,NA,NA,40,NA,0.537,"Fv/Fm",1,NA,0.016,NA,0.009,3,0.8,0.025,3.1,1.468
"496",496,566,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.272,"Fv/Fm","quantum yield","phys","dQ",NA,0.034,NA,0.02,3,NA,NA,40,NA,0.459,"Fv/Fm",1,NA,0.006,NA,0.003,3,0.8,0.025,6.094,3.761
"497",497,567,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.45,"Fv/Fm","quantum yield","phys","dQ",NA,0.008,NA,0.005,3,NA,NA,40,NA,0.47,"Fv/Fm",1,NA,0.024,NA,0.014,3,0.8,0.018,0.894,0.733
"498",498,568,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",2,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.477,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.487,"Fv/Fm",1,NA,0.034,NA,0.02,3,0.8,0.024,0.328,0.676
"499",499,479,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.564,"Chl a (µg/L)","biomass","biom","SS",NA,0.079,NA,0.046,3,NA,NA,40,NA,0.325,"Chl a (µg/L)",2,NA,0.027,NA,0.015,3,0.8,0.059,-3.238,1.54
"500",500,480,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.733,"Chl a (µg/L)","biomass","biom","SS",NA,0.096,NA,0.056,3,NA,NA,40,NA,0.391,"Chl a (µg/L)",2,NA,0.037,NA,0.021,3,0.8,0.073,-3.753,1.84
"501",501,481,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.995,"Chl a (µg/L)","biomass","biom","SS",NA,0.046,NA,0.027,3,NA,NA,40,NA,0.311,"Chl a (µg/L)",2,NA,0.106,NA,0.061,3,0.8,0.082,-6.687,4.393
"502",502,482,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.677,"Chl a (µg/L)","biomass","biom","SS",NA,0.101,NA,0.058,3,NA,NA,40,NA,0.24,"Chl a (µg/L)",2,NA,0.055,NA,0.032,3,0.8,0.081,-4.312,2.216
"503",503,483,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.951,"Chl a (µg/L)","biomass","biom","SS",NA,0.049,NA,0.028,3,NA,NA,40,NA,0.65,"Chl a (µg/L)",2,NA,1.029,NA,0.594,3,0.8,0.729,-0.33,0.676
"504",504,484,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,1.128,"Chl a (µg/L)","biomass","biom","SS",NA,0.138,NA,0.08,3,NA,NA,40,NA,0.464,"Chl a (µg/L)",2,NA,0.028,NA,0.016,3,0.8,0.099,-5.342,3.045
"505",505,509,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.497,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.554,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.008,5.433,3.126
"506",506,510,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.515,"Fv/Fm","quantum yield","phys","dQ",NA,0.018,NA,0.01,3,NA,NA,40,NA,0.56,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.015,2.418,1.154
"507",507,511,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.506,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.006,3,NA,NA,40,NA,0.492,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.01,-1.12,0.771
"508",508,512,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.453,"Fv/Fm","quantum yield","phys","dQ",NA,0.014,NA,0.008,3,NA,NA,40,NA,0.512,"Fv/Fm",1,NA,0.028,NA,0.016,3,0.8,0.022,2.096,1.033
"509",509,513,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.534,"Fv/Fm","quantum yield","phys","dQ",NA,0.046,NA,0.027,3,NA,NA,40,NA,0.522,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.033,-0.288,0.674
"510",510,514,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.481,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.507,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.008,2.522,1.197
"511",511,539,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.442,"Chl a (µg/L)","biomass","biom","SS",NA,0.066,NA,0.038,3,NA,NA,40,NA,0.312,"Chl a (µg/L)",2,NA,0.01,NA,0.006,3,0.8,0.047,-2.22,1.077
"512",512,540,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.592,"Chl a (µg/L)","biomass","biom","SS",NA,0.125,NA,0.072,3,NA,NA,40,NA,0.413,"Chl a (µg/L)",2,NA,0.034,NA,0.02,3,0.8,0.091,-1.567,0.871
"513",513,541,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.64,"Chl a (µg/L)","biomass","biom","SS",NA,0.053,NA,0.03,3,NA,NA,40,NA,0.275,"Chl a (µg/L)",2,NA,0.066,NA,0.038,3,0.8,0.06,-4.915,2.68
"514",514,542,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.363,"Chl a (µg/L)","biomass","biom","SS",NA,0.059,NA,0.034,3,NA,NA,40,NA,0.242,"Chl a (µg/L)",2,NA,0.074,NA,0.043,3,0.8,0.067,-1.448,0.841
"515",515,543,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.767,"Chl a (µg/L)","biomass","biom","SS",NA,0.623,NA,0.36,3,NA,NA,40,NA,0.208,"Chl a (µg/L)",2,NA,0.031,NA,0.018,3,0.8,0.441,-1.013,0.752
"516",516,544,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.895,"Chl a (µg/L)","biomass","biom","SS",NA,0.121,NA,0.07,3,NA,NA,40,NA,0.509,"Chl a (µg/L)",2,NA,0.062,NA,0.036,3,0.8,0.096,-3.212,1.526
"517",517,569,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.497,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.552,"Fv/Fm",1,NA,0.016,NA,0.009,3,0.8,0.014,3.055,1.444
"518",518,570,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.471,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.532,"Fv/Fm",1,NA,0.02,NA,0.012,3,0.8,0.017,2.91,1.373
"519",519,571,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.45,"Fv/Fm","quantum yield","phys","dQ",NA,0.032,NA,0.019,3,NA,NA,40,NA,0.47,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.023,0.686,0.706
"520",520,572,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.301,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.012,3,NA,NA,40,NA,0.478,"Fv/Fm",1,NA,0.016,NA,0.009,3,0.8,0.018,7.774,5.703
"521",521,573,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.412,"Fv/Fm","quantum yield","phys","dQ",NA,0.004,NA,0.002,3,NA,NA,40,NA,0.51,"Fv/Fm",1,NA,0.07,NA,0.041,3,0.8,0.05,1.581,0.875
"522",522,574,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",3,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.443,"Fv/Fm","quantum yield","phys","dQ",NA,0.026,NA,0.015,3,NA,NA,40,NA,0.471,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.019,1.165,0.78
"523",523,485,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.385,"Chl a (µg/L)","biomass","biom","SS",NA,0.051,NA,0.03,3,NA,NA,40,NA,0.316,"Chl a (µg/L)",2,NA,0.035,NA,0.02,3,0.8,0.044,-1.256,0.798
"524",524,486,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,1.027,"Chl a (µg/L)","biomass","biom","SS",NA,0.601,NA,0.347,3,NA,NA,40,NA,0.276,"Chl a (µg/L)",2,NA,0.013,NA,0.007,3,0.8,0.425,-1.414,0.833
"525",525,487,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,1.185,"Chl a (µg/L)","biomass","biom","SS",NA,0.219,NA,0.126,3,NA,NA,40,NA,0.354,"Chl a (µg/L)",2,NA,0.016,NA,0.009,3,0.8,0.155,-4.288,2.199
"526",526,488,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,2.764,"Chl a (µg/L)","biomass","biom","SS",NA,1.235,NA,0.713,3,NA,NA,40,NA,0.177,"Chl a (µg/L)",2,NA,0.076,NA,0.044,3,0.8,0.875,-2.365,1.133
"527",527,489,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,3.083,"Chl a (µg/L)","biomass","biom","SS",NA,0.286,NA,0.165,3,NA,NA,40,NA,0.225,"Chl a (µg/L)",2,NA,0.012,NA,0.007,3,0.8,0.202,-11.318,11.341
"528",528,490,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,1.068,"Chl a (µg/L)","biomass","biom","SS",NA,0.117,NA,0.068,3,NA,NA,40,NA,0.673,"Chl a (µg/L)",2,NA,0.057,NA,0.033,3,0.8,0.092,-3.436,1.651
"529",529,515,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.519,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.501,"Fv/Fm",1,NA,0.026,NA,0.015,3,0.8,0.02,-0.711,0.709
"530",530,516,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.495,"Fv/Fm","quantum yield","phys","dQ",NA,0.018,NA,0.01,3,NA,NA,40,NA,0.521,"Fv/Fm",1,NA,0.004,NA,0.002,3,0.8,0.013,1.595,0.879
"531",531,517,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.496,"Fv/Fm","quantum yield","phys","dQ",NA,0.022,NA,0.013,3,NA,NA,40,NA,0.486,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.017,-0.483,0.686
"532",532,518,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.424,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.012,3,NA,NA,40,NA,0.562,"Fv/Fm",1,NA,0.068,NA,0.039,3,0.8,0.05,2.203,1.071
"533",533,519,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.533,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.012,3,NA,NA,40,NA,0.531,"Fv/Fm",1,NA,0.004,NA,0.002,3,0.8,0.014,-0.111,0.668
"534",534,520,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.482,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.476,"Fv/Fm",1,NA,0.014,NA,0.008,3,0.8,0.011,-0.446,0.683
"535",535,545,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.287,"Chl a (µg/L)","biomass","biom","SS",NA,0.022,NA,0.012,3,NA,NA,40,NA,0.373,"Chl a (µg/L)",2,NA,0.061,NA,0.035,3,0.8,0.046,1.511,0.857
"536",536,546,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.463,"Chl a (µg/L)","biomass","biom","SS",NA,0.091,NA,0.053,3,NA,NA,40,NA,0.305,"Chl a (µg/L)",2,NA,0.044,NA,0.025,3,0.8,0.072,-1.759,0.925
"537",537,547,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.798,"Chl a (µg/L)","biomass","biom","SS",NA,0.169,NA,0.097,3,NA,NA,40,NA,0.313,"Chl a (µg/L)",2,NA,0.058,NA,0.033,3,0.8,0.126,-3.079,1.457
"538",538,548,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.398,"Chl a (µg/L)","biomass","biom","SS",NA,0.121,NA,0.07,3,NA,NA,40,NA,0.19,"Chl a (µg/L)",2,NA,0.079,NA,0.045,3,0.8,0.102,-1.629,0.888
"539",539,549,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.757,"Chl a (µg/L)","biomass","biom","SS",NA,0.113,NA,0.065,3,NA,NA,40,NA,0.246,"Chl a (µg/L)",2,NA,0.023,NA,0.013,3,0.8,0.082,-5.019,2.766
"540",540,550,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.547,"Chl a (µg/L)","biomass","biom","SS",NA,0.039,NA,0.023,3,NA,NA,40,NA,0.721,"Chl a (µg/L)",2,NA,0.07,NA,0.04,3,0.8,0.057,2.468,1.174
"541",541,575,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.53,"Fv/Fm","quantum yield","phys","dQ",NA,0.03,NA,0.017,3,NA,NA,40,NA,0.53,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.022,0,0.667
"542",542,576,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.405,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.53,"Fv/Fm",1,NA,0.014,NA,0.008,3,0.8,0.013,7.608,5.491
"543",543,577,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.437,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.012,3,NA,NA,40,NA,0.467,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.016,1.518,0.859
"544",544,578,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.263,"Fv/Fm","quantum yield","phys","dQ",NA,0.004,NA,0.002,3,NA,NA,40,NA,0.508,"Fv/Fm",1,NA,0.064,NA,0.037,3,0.8,0.046,4.305,2.211
"545",545,579,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.37,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.513,"Fv/Fm",1,NA,0.006,NA,0.003,3,0.8,0.006,18.938,30.555
"546",546,580,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",4,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.414,"Fv/Fm","quantum yield","phys","dQ",NA,0.032,NA,0.018,3,NA,NA,40,NA,0.414,"Fv/Fm",1,NA,0.03,NA,0.017,3,0.8,0.031,0,0.667
"547",547,491,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.338,"Chl a (µg/L)","biomass","biom","SS",NA,0.014,NA,0.008,3,NA,NA,40,NA,0.327,"Chl a (µg/L)",2,NA,0.025,NA,0.014,3,0.8,0.02,-0.441,0.683
"548",548,492,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,2.702,"Chl a (µg/L)","biomass","biom","SS",NA,0.321,NA,0.185,3,NA,NA,40,NA,0.261,"Chl a (µg/L)",2,NA,0.025,NA,0.014,3,0.8,0.228,-8.574,6.792
"549",549,493,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,1.913,"Chl a (µg/L)","biomass","biom","SS",NA,0.512,NA,0.295,3,NA,NA,40,NA,0.254,"Chl a (µg/L)",2,NA,0.11,NA,0.064,3,0.8,0.37,-3.588,1.739
"550",550,494,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,3.246,"Chl a (µg/L)","biomass","biom","SS",NA,0.658,NA,0.38,3,NA,NA,40,NA,0.161,"Chl a (µg/L)",2,NA,0.012,NA,0.007,3,0.8,0.465,-5.3,3.008
"551",551,495,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,2.822,"Chl a (µg/L)","biomass","biom","SS",NA,0.381,NA,0.22,3,NA,NA,40,NA,0.203,"Chl a (µg/L)",2,NA,0.008,NA,0.005,3,0.8,0.269,-7.783,5.715
"552",552,496,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)","No values available","Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,NA,NA,NA,2,NA,NA,100,NA,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,NA,NA,40,NA,NA,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"553",553,521,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.499,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.523,"Fv/Fm",1,NA,0.018,NA,0.01,3,0.8,0.014,1.431,0.837
"554",554,522,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.544,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.006,3,NA,NA,40,NA,0.536,"Fv/Fm",1,NA,0.03,NA,0.017,3,0.8,0.023,-0.286,0.673
"555",555,523,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.477,"Fv/Fm","quantum yield","phys","dQ",NA,0.018,NA,0.01,3,NA,NA,40,NA,0.513,"Fv/Fm",1,NA,0.081,NA,0.046,3,0.8,0.058,0.496,0.687
"556",556,524,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.348,"Fv/Fm","quantum yield","phys","dQ",NA,0.024,NA,0.014,3,NA,NA,40,NA,0.685,"Fv/Fm",1,NA,0.026,NA,0.015,3,0.8,0.025,10.744,10.285
"557",557,525,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.559,"Fv/Fm","quantum yield","phys","dQ",NA,0.008,NA,0.005,3,NA,NA,40,NA,0.523,"Fv/Fm",1,NA,0.016,NA,0.009,3,0.8,0.013,-2.276,1.098
"558",558,526,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","nutrients","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.52,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.012,3,NA,NA,40,NA,0.508,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.016,-0.607,0.697
"559",559,551,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.323,"Chl a (µg/L)","biomass","biom","SS",NA,0.053,NA,0.03,3,NA,NA,40,NA,0.375,"Chl a (µg/L)",2,NA,0.042,NA,0.024,3,0.8,0.047,0.888,0.732
"560",560,552,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,1.441,"Chl a (µg/L)","biomass","biom","SS",NA,0.843,NA,0.486,3,NA,NA,40,NA,0.193,"Chl a (µg/L)",2,NA,0.071,NA,0.041,3,0.8,0.598,-1.669,0.899
"561",561,553,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.811,"Chl a (µg/L)","biomass","biom","SS",NA,0.087,NA,0.05,3,NA,NA,40,NA,0.34,"Chl a (µg/L)",2,NA,0.024,NA,0.014,3,0.8,0.064,-5.918,3.586
"562",562,554,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.536,"Chl a (µg/L)","biomass","biom","SS",NA,0.066,NA,0.038,3,NA,NA,40,NA,0.151,"Chl a (µg/L)",2,NA,0.033,NA,0.019,3,0.8,0.052,-5.953,3.62
"563",563,555,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 4",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.927,"Chl a (µg/L)","biomass","biom","SS",NA,0.411,NA,0.237,3,NA,NA,40,NA,0.382,"Chl a (µg/L)",2,NA,0.03,NA,0.017,3,0.8,0.291,-1.496,0.853
"564",564,556,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)","No values available","Fig 4",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,NA,NA,NA,2,NA,NA,100,NA,NA,"Chl a (µg/L)","biomass","biom","SS",NA,NA,NA,NA,3,NA,NA,40,NA,NA,"Chl a (µg/L)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"565",565,581,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,149,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.2,0.3,0.2,0.3,NA,4,NA,NA,100,NA,0.515,"Fv/Fm","quantum yield","phys","dQ",NA,0.012,NA,0.007,3,NA,NA,40,NA,0.525,"Fv/Fm",1,NA,0.014,NA,0.008,3,0.8,0.013,0.58,0.695
"566",566,582,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,165,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,30,NA,NA,NA,0.1,5.8,0.1,5.8,NA,4,NA,NA,100,NA,0.399,"Fv/Fm","quantum yield","phys","dQ",NA,0.054,NA,0.031,3,NA,NA,40,NA,0.566,"Fv/Fm",1,NA,0.004,NA,0.002,3,0.8,0.039,3.468,1.669
"567",567,583,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.4,1.8,0.4,1.8,NA,4,NA,NA,100,NA,0.416,"Fv/Fm","quantum yield","phys","dQ",NA,0.018,NA,0.01,3,NA,NA,40,NA,0.489,"Fv/Fm",1,NA,0.006,NA,0.003,3,0.8,0.013,4.299,2.207
"568",568,584,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",0,-140,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,29,NA,NA,NA,0.5,6.5,0.5,6.5,NA,4,NA,NA,100,NA,0.213,"Fv/Fm","quantum yield","phys","dQ",NA,0.028,NA,0.016,3,NA,NA,40,NA,0.617,"Fv/Fm",1,NA,0.04,NA,0.023,3,0.8,0.035,9.315,7.898
"569",569,585,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-9,-170,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,28,NA,NA,NA,0.5,4.3,0.5,4.3,NA,4,NA,NA,100,NA,0.336,"Fv/Fm","quantum yield","phys","dQ",NA,0.006,NA,0.003,3,NA,NA,40,NA,0.509,"Fv/Fm",1,NA,0.004,NA,0.002,3,0.8,0.005,26.975,61.306
"570",570,586,"280","Johnson, ZI; Shyam, R; Ritchie, AE; Mioni, C; Lance, VP; Murray, JW; Zinser, ER",2010,"The effect of iron- and light-limitation on phytoplankton communities of deep chlorophyll maxima of the western Pacific Ocean","JOURNAL OF MARINE RESEARCH",1,"Nutrients were not always sampled at exactly the same depth as the sample water; Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Field","offshore",-32,163,"Pacific Ocean","Total phytoplankton","phytoplankton",5,"in situ incubation","Polycarbonate bottles",0.5,NA,"yes","none","shading screen","natural",NA,NA,19,NA,NA,NA,0.3,2.2,0.3,2.2,NA,4,NA,NA,100,NA,0.366,"Fv/Fm","quantum yield","phys","dQ",NA,0.022,NA,0.013,3,NA,NA,40,NA,0.466,"Fv/Fm",1,NA,0.012,NA,0.007,3,0.8,0.018,4.516,2.366
"571",571,587,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,2,NA,0.9,NA,0.324,"Growth rate (µ/d)",2,NA,0.004,NA,0.002,3,0.8,0.009,-29.456,72.974
"572",572,588,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,4,NA,1.7,NA,0.405,"Growth rate (µ/d)",2,NA,0.016,NA,0.009,3,0.8,0.014,-14.104,17.245
"573",573,589,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,7,NA,3,NA,0.497,"Growth rate (µ/d)",2,NA,0.034,NA,0.02,3,0.8,0.025,-5.067,2.806
"574",574,590,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,15,NA,6.5,NA,0.424,"Growth rate (µ/d)",2,NA,0.024,NA,0.014,3,0.8,0.019,-9.726,8.549
"575",575,591,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,30,NA,13,NA,0.646,"Growth rate (µ/d)",2,NA,0.024,NA,0.014,3,0.8,0.019,-0.506,0.688
"576",576,592,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,60,NA,26.1,NA,0.655,"Growth rate (µ/d)",2,NA,0.015,NA,0.009,3,0.8,0.014,-0.159,0.669
"577",577,593,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,90,NA,39.1,NA,0.655,"Growth rate (µ/d)",2,NA,0.015,NA,0.009,3,0.8,0.014,-0.159,0.669
"578",578,594,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,110,NA,47.8,NA,0.677,"Growth rate (µ/d)",2,NA,0.024,NA,0.014,3,0.8,0.019,0.787,0.718
"579",579,595,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,140,NA,60.9,NA,0.647,"Growth rate (µ/d)",2,NA,0.042,NA,0.024,3,0.8,0.031,-0.28,0.673
"580",580,596,"287","Xu, N; Duan, SS; Li, AF; Zhang, CW; Cai, ZP; Hu, ZX",2010,"Effects of temperature, salinity and irradiance on the growth of the harmful dinoflagellate Prorocentrum donghaiense Lu","HARMFUL ALGAE",1,NA,NA,"Fig 1",NA,"2010","Lab","coastal",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",7,"microcosm","test tube",0.05,NA,"no","none","shading screen","12",NA,NA,24,NA,NA,30.5,36.3,882,36.3,882,NA,4,230,NA,100,NA,0.658,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.012,NA,0.007,3,170,NA,73.9,NA,0.665,"Growth rate (µ/d)",2,NA,0.005,NA,0.003,3,0.8,0.009,0.574,0.694
"581",581,635,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",6,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,63.97,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,2.29,NA,1.325,3,NA,NA,58,NA,64.323,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,5.812,NA,3.355,3,0.8,4.418,0.064,0.667
"582",582,640,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",6,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,63.97,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,2.29,NA,1.325,3,NA,NA,34,NA,58.937,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,2.294,NA,1.324,3,0.8,2.294,-1.755,0.923
"583",583,645,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",6,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,63.97,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,2.29,NA,1.325,3,NA,NA,11,NA,56.288,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,0.918,NA,0.53,3,0.8,1.747,-3.517,1.698
"584",584,650,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",6,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,100.295,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,11.24,NA,6.492,3,NA,NA,58,NA,87.41,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,2.896,NA,1.672,3,0.8,8.21,-1.256,0.798
"585",585,655,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",6,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,100.295,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,11.24,NA,6.492,3,NA,NA,34,NA,77.082,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,5.281,NA,3.049,3,0.8,8.784,-2.114,1.039
"586",586,660,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",6,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,100.295,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,11.24,NA,6.492,3,NA,NA,11,NA,80.23,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,2.385,NA,1.377,3,0.8,8.128,-1.975,0.992
"587",587,634,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",19,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,65.286,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,7.04,NA,4.062,3,NA,NA,58,NA,71.82,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,9.482,NA,5.475,3,0.8,8.349,0.626,0.699
"588",588,639,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",19,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,65.286,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,7.04,NA,4.062,3,NA,NA,34,NA,67.891,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,2.829,NA,1.634,3,0.8,5.362,0.389,0.679
"589",589,644,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",19,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,65.286,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,7.04,NA,4.062,3,NA,NA,11,NA,56.191,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,7.494,NA,4.327,3,0.8,7.268,-1.001,0.75
"590",590,649,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",19,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,107.377,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,7.5,NA,4.328,3,NA,NA,58,NA,113.475,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,8.518,NA,4.918,3,0.8,8.023,0.608,0.697
"591",591,654,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",19,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,107.377,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,7.5,NA,4.328,3,NA,NA,34,NA,99.508,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,12.607,NA,7.279,3,0.8,10.371,-0.607,0.697
"592",592,659,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",19,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,107.377,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,7.5,NA,4.328,3,NA,NA,11,NA,79.246,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,15.674,NA,9.049,3,0.8,12.285,-1.832,0.946
"593",593,597,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,1056,NA,72.9,NA,30.505,"ETRm (µmol e m-2 s-1)",1,NA,10.146,NA,4.142,6,0.923,8.623,0.1,0.334
"594",594,598,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,701,NA,48.4,NA,30.066,"ETRm (µmol e m-2 s-1)",1,NA,6.765,NA,2.762,6,0.923,6.765,0.068,0.334
"595",595,599,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,492,NA,34,NA,30.238,"ETRm (µmol e m-2 s-1)",1,NA,5.798,NA,2.367,6,0.923,6.3,0.098,0.334
"596",596,600,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,316,NA,21.8,NA,32.386,"ETRm (µmol e m-2 s-1)",1,NA,4.348,NA,1.775,6,0.923,5.686,0.458,0.342
"597",597,601,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,207,NA,14.3,NA,29.414,"ETRm (µmol e m-2 s-1)",1,NA,2.416,NA,0.986,6,0.923,5.079,-0.028,0.333
"598",598,602,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,98,NA,6.8,NA,20.328,"ETRm (µmol e m-2 s-1)",1,NA,0.966,NA,0.394,6,0.923,4.832,-1.765,0.463
"599",599,603,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,29.567,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,6.76,NA,2.762,6,30,NA,2.1,NA,8.09,"ETRm (µmol e m-2 s-1)",1,NA,0.483,NA,0.197,6,0.923,4.795,-4.134,1.045
"600",600,611,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,1056,NA,72.9,NA,48.848,"ETRm (µmol e m-2 s-1)",1,NA,7.731,NA,3.156,6,0.923,8.486,-0.027,0.333
"601",601,612,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,701,NA,48.4,NA,48.41,"ETRm (µmol e m-2 s-1)",1,NA,6.28,NA,2.564,6,0.923,7.865,-0.08,0.334
"602",602,613,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,492,NA,34,NA,47.99,"ETRm (µmol e m-2 s-1)",1,NA,3.866,NA,1.578,6,0.923,7.043,-0.145,0.334
"603",603,614,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,316,NA,21.8,NA,42.642,"ETRm (µmol e m-2 s-1)",1,NA,3.382,NA,1.381,6,0.923,6.918,-0.861,0.364
"604",604,615,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,207,NA,14.3,NA,38.684,"ETRm (µmol e m-2 s-1)",1,NA,3.866,NA,1.578,6,0.923,7.043,-1.364,0.411
"605",605,616,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,98,NA,6.8,NA,23.089,"ETRm (µmol e m-2 s-1)",1,NA,1.449,NA,0.592,6,0.923,6.572,-3.653,0.889
"606",606,617,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1449,NA,100,NA,49.094,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,9.18,NA,3.748,6,30,NA,2.1,NA,7.893,"ETRm (µmol e m-2 s-1)",1,NA,2.416,NA,0.986,6,0.923,6.712,-5.666,1.671
"607",607,664,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.679,"Fv/Fm","quantum yield","phys","dQ",NA,0.03,NA,0.016,3,NA,NA,58,NA,0.706,"Fv/Fm",1,NA,0.005,NA,0.003,3,0.8,0.02,1.082,0.764
"608",608,668,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.679,"Fv/Fm","quantum yield","phys","dQ",NA,0.03,NA,0.016,3,NA,NA,34,NA,0.77,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.02,3.594,1.743
"609",609,672,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",20,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.679,"Fv/Fm","quantum yield","phys","dQ",NA,0.03,NA,0.016,3,NA,NA,11,NA,0.772,"Fv/Fm",1,NA,0.006,NA,0.004,3,0.8,0.02,3.689,1.801
"610",610,604,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,1267,NA,72.6,NA,73.428,"ETRm (µmol e m-2 s-1)",1,NA,14.906,NA,6.085,6,0.923,13.947,-0.013,0.333
"611",611,605,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,841,NA,48.2,NA,73.631,"ETRm (µmol e m-2 s-1)",1,NA,10.931,NA,4.462,6,0.923,11.966,0,0.333
"612",612,606,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,594,NA,34.1,NA,69.777,"ETRm (µmol e m-2 s-1)",1,NA,14.906,NA,6.085,6,0.923,13.947,-0.255,0.336
"613",613,607,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,377,NA,21.6,NA,62.272,"ETRm (µmol e m-2 s-1)",1,NA,7.453,NA,3.043,6,0.923,10.546,-0.994,0.375
"614",614,608,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,250,NA,14.3,NA,53.753,"ETRm (µmol e m-2 s-1)",1,NA,4.472,NA,1.826,6,0.923,9.666,-1.898,0.483
"615",615,609,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,116,NA,6.7,NA,30.426,"ETRm (µmol e m-2 s-1)",1,NA,1.491,NA,0.609,6,0.923,9.195,-4.337,1.117
"616",616,610,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,73.631,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.92,NA,5.274,6,39,NA,2.2,NA,10.142,"ETRm (µmol e m-2 s-1)",1,NA,3.478,NA,1.42,6,0.923,9.46,-6.195,1.933
"617",617,618,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,1267,NA,72.6,NA,77.688,"ETRm (µmol e m-2 s-1)",1,NA,9.44,NA,3.854,6,0.923,11.032,0.034,0.333
"618",618,619,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,841,NA,48.2,NA,74.037,"ETRm (µmol e m-2 s-1)",1,NA,14.409,NA,5.882,6,0.923,13.452,-0.223,0.335
"619",619,620,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,594,NA,34.1,NA,71.197,"ETRm (µmol e m-2 s-1)",1,NA,7.453,NA,3.043,6,0.923,10.243,-0.548,0.346
"620",620,621,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,377,NA,21.6,NA,62.677,"ETRm (µmol e m-2 s-1)",1,NA,8.943,NA,3.651,6,0.923,10.823,-1.246,0.398
"621",621,622,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,250,NA,14.3,NA,53.955,"ETRm (µmol e m-2 s-1)",1,NA,4.472,NA,1.826,6,0.923,9.335,-2.307,0.555
"622",622,623,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,116,NA,6.7,NA,30.223,"ETRm (µmol e m-2 s-1)",1,NA,2.484,NA,1.014,6,0.923,8.957,-4.85,1.313
"623",623,624,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 1","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina mature plants","seagrass",28,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1744,NA,100,NA,77.282,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,12.42,NA,5.071,6,39,NA,2.2,NA,10.142,"ETRm (µmol e m-2 s-1)",1,NA,1.987,NA,0.811,6,0.923,8.895,-6.967,2.356
"624",624,663,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",32,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.716,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.011,3,NA,NA,58,NA,0.689,"Fv/Fm",1,NA,0.016,NA,0.009,3,0.8,0.017,-1.243,0.795
"625",625,667,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",32,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.716,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.011,3,NA,NA,34,NA,0.759,"Fv/Fm",1,NA,0.014,NA,0.008,3,0.8,0.016,2.078,1.027
"626",626,671,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",32,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.716,"Fv/Fm","quantum yield","phys","dQ",NA,0.02,NA,0.011,3,NA,NA,11,NA,0.79,"Fv/Fm",1,NA,0.008,NA,0.005,3,0.8,0.014,4.171,2.117
"627",627,633,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",40,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,75.604,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,3.98,NA,2.296,3,NA,NA,58,NA,65.494,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,8.794,NA,5.077,3,0.8,6.824,-1.185,0.784
"628",628,638,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",40,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,75.604,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,3.98,NA,2.296,3,NA,NA,34,NA,46.597,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,5.2,NA,3.002,3,0.8,4.629,-5.013,2.761
"629",629,643,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",40,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,75.604,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,3.98,NA,2.296,3,NA,NA,11,NA,42.138,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,4.588,NA,2.649,3,0.8,4.293,-6.236,3.907
"630",630,648,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",40,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,113.18,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,10.22,NA,5.902,3,NA,NA,58,NA,93.311,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,10.052,NA,5.803,3,0.8,10.137,-1.568,0.872
"631",631,653,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",40,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,113.18,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,10.22,NA,5.902,3,NA,NA,34,NA,62.721,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,8.348,NA,4.82,3,0.8,9.332,-4.326,2.226
"632",632,658,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",40,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,113.18,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,10.22,NA,5.902,3,NA,NA,11,NA,57.016,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,7.837,NA,4.525,3,0.8,9.108,-4.933,2.695
"633",633,632,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",47,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,80.103,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,8.11,NA,4.68,3,NA,NA,58,NA,70.081,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,12.923,NA,7.461,3,0.8,10.787,-0.743,0.713
"634",634,637,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",47,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,80.103,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,8.11,NA,4.68,3,NA,NA,34,NA,64.562,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,7.188,NA,4.15,3,0.8,7.661,-1.623,0.886
"635",635,642,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",47,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,80.103,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,8.11,NA,4.68,3,NA,NA,11,NA,52.465,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,3.518,NA,2.031,3,0.8,6.248,-3.539,1.71
"636",636,647,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",47,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,127.344,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,27.94,NA,16.131,3,NA,NA,58,NA,105.115,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,20.955,NA,12.098,3,0.8,24.696,-0.72,0.71
"637",637,652,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",47,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,127.344,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,27.94,NA,16.131,3,NA,NA,34,NA,100.492,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,19.251,NA,11.115,3,0.8,23.992,-0.895,0.733
"638",638,657,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",47,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,127.344,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,27.94,NA,16.131,3,NA,NA,11,NA,70.59,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,5.452,NA,3.148,3,0.8,20.129,-2.256,1.091
"639",639,662,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",56,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.742,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.005,3,NA,NA,58,NA,0.764,"Fv/Fm",1,NA,0.004,NA,0.002,3,0.8,0.007,2.496,1.186
"640",640,666,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",56,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.742,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.005,3,NA,NA,34,NA,0.773,"Fv/Fm",1,NA,0.01,NA,0.006,3,0.8,0.01,2.541,1.205
"641",641,670,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",56,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.742,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.005,3,NA,NA,11,NA,0.789,"Fv/Fm",1,NA,0.005,NA,0.003,3,0.8,0.007,5.064,2.804
"642",642,625,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 2A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,90.216,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.23,NA,6.484,3,NA,NA,58,NA,74.823,"ETRm (µmol e m-2 s-1)",1,NA,3.063,NA,1.768,3,0.8,8.231,-1.496,0.853
"643",643,626,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 2A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,90.216,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.23,NA,6.484,3,NA,NA,34,NA,67.661,"ETRm (µmol e m-2 s-1)",1,NA,3.063,NA,1.768,3,0.8,8.231,-2.192,1.067
"644",644,627,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 2A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,90.216,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,11.23,NA,6.484,3,NA,NA,11,NA,47.531,"ETRm (µmol e m-2 s-1)",1,NA,6.533,NA,3.772,3,0.8,9.187,-3.717,1.818
"645",645,628,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 2B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.762,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.007,3,NA,NA,58,NA,0.751,"Fv/Fm",1,NA,0.015,NA,0.009,3,0.8,0.014,-0.649,0.702
"646",646,629,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 2B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.762,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.007,3,NA,NA,34,NA,0.775,"Fv/Fm",1,NA,0.017,NA,0.01,3,0.8,0.014,0.745,0.713
"647",647,630,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 2B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.762,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.007,3,NA,NA,11,NA,0.811,"Fv/Fm",1,NA,0.007,NA,0.004,3,0.8,0.009,4.14,2.095
"648",648,631,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,90.336,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,10.71,NA,6.181,3,NA,NA,58,NA,74.883,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,3.365,NA,1.943,3,0.8,7.935,-1.558,0.869
"649",649,636,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,90.336,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,10.71,NA,6.181,3,NA,NA,34,NA,67.554,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,2.218,NA,1.28,3,0.8,7.731,-2.357,1.13
"650",650,641,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,90.336,"Maximum electron transport rate (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,10.71,NA,6.181,3,NA,NA,11,NA,47.687,"Maximum electron transport rate (µmol e m-2 s-1)",1,NA,5.659,NA,3.267,3,0.8,8.563,-3.985,1.99
"651",651,646,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,137.279,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,23.68,NA,13.672,3,NA,NA,58,NA,115.049,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,9.2,NA,5.311,3,0.8,17.964,-0.99,0.748
"652",652,651,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,137.279,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,23.68,NA,13.672,3,NA,NA,34,NA,97.934,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,5.111,NA,2.951,3,0.8,17.13,-1.837,0.948
"653",653,656,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,137.279,"Minimum saturation irradiance (µmol photons m-2 s-1)","quantum yield","phys","dQ",NA,23.68,NA,13.672,3,NA,NA,11,NA,64.492,"Minimum saturation irradiance (µmol photons m-2 s-1)",1,NA,8.518,NA,4.918,3,0.8,17.795,-3.272,1.559
"654",654,661,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.768,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.007,3,NA,NA,58,NA,0.756,"Fv/Fm",1,NA,0.017,NA,0.01,3,0.8,0.015,-0.636,0.7
"655",655,665,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.768,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.007,3,NA,NA,34,NA,0.782,"Fv/Fm",1,NA,0.019,NA,0.011,3,0.8,0.016,0.659,0.703
"656",656,669,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",63,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.768,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.007,3,NA,NA,11,NA,0.821,"Fv/Fm",1,NA,0.007,NA,0.004,3,0.8,0.01,4.057,2.038
"657",657,673,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,16.864,"Shoots/plant","abundance","biom","SS",NA,7.21,NA,4.163,3,NA,NA,58,NA,10.562,"Shoots/plant",2,NA,5.448,NA,3.146,3,0.8,6.39,-0.789,0.719
"658",658,674,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,16.864,"Shoots/plant","abundance","biom","SS",NA,7.21,NA,4.163,3,NA,NA,34,NA,4.549,"Shoots/plant",2,NA,1.229,NA,0.71,3,0.8,5.172,-1.905,0.969
"659",659,675,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4A","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,16.864,"Shoots/plant","abundance","biom","SS",NA,7.21,NA,4.163,3,NA,NA,11,NA,1.067,"Shoots/plant",2,NA,0.574,NA,0.331,3,0.8,5.114,-2.471,1.175
"660",660,676,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.113,"Rhizome growth (g dryweight plant-1 day-1)","growth rate","biom","dSS",NA,0.01,NA,0.007,3,NA,NA,58,NA,0.068,"Rhizome growth (g dryweight plant-1 day-1)",2,NA,0.043,NA,0.025,3,0.8,0.032,-1.136,0.774
"661",661,677,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.113,"Rhizome growth (g dryweight plant-1 day-1)","growth rate","biom","dSS",NA,0.01,NA,0.007,3,NA,NA,34,NA,0.017,"Rhizome growth (g dryweight plant-1 day-1)",2,NA,0.002,NA,0.001,3,0.8,0.009,-8.748,7.044
"662",662,678,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4B","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.113,"Rhizome growth (g dryweight plant-1 day-1)","growth rate","biom","dSS",NA,0.01,NA,0.007,3,NA,NA,11,NA,4e-04,"Rhizome growth (g dryweight plant-1 day-1)",2,NA,0.001,NA,0.001,3,0.8,0.009,-10.258,9.435
"663",663,679,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.21,"New shoots/day","growth rate","biom","dSS",NA,0.08,NA,0.046,3,NA,NA,58,NA,0.1,"New shoots/day",2,NA,0.052,NA,0.03,3,0.8,0.068,-1.298,0.807
"664",664,680,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.21,"New shoots/day","growth rate","biom","dSS",NA,0.08,NA,0.046,3,NA,NA,34,NA,0.049,"New shoots/day",2,NA,0.017,NA,0.01,3,0.8,0.058,-2.227,1.08
"665",665,681,"288","Ochieng, CA; Short, FT; Walker, DI",2010,"Photosynthetic and morphological responses of eelgrass (Zostera marina L.) to a gradient of light conditions","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 4C","spring","2010","Field","coastal",43.07,-70.88,"Great Bay Estuary, USA","Zostera marina seedlings","seagrass",81,"mesocosm","tank",1000,NA,"yes","none","shading screen","natural",308,NA,20.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.21,"New shoots/day","growth rate","biom","dSS",NA,0.08,NA,0.046,3,NA,NA,11,NA,0.006,"New shoots/day",2,NA,0.012,NA,0.007,3,0.8,0.057,-2.858,1.347
"666",666,682,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",46,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,37.594,"Biomass (µg C/L)","biomass","biom","SS",NA,NA,NA,NA,2,NA,NA,75,NA,31.486,"Biomass (µg C/L)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"667",667,702,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",46,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,53.258,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,75,NA,50.378,"Biomass (µg C/L)",2,NA,26.717,NA,18.892,2,0.571,24.541,-0.067,1.001
"668",668,722,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",46,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,37.594,"Biomass (µg C/L)","biomass","biom","SS",NA,0,NA,0,2,NA,NA,50,NA,50.378,"Biomass (µg C/L)",2,NA,17.811,NA,12.594,2,0.571,12.594,0.58,1.042
"669",669,742,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",46,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,53.258,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,50,NA,56.675,"Biomass (µg C/L)",2,NA,26.717,NA,18.892,2,0.571,24.541,0.08,1.001
"670",670,683,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)","No CTRL STD or STE available","Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,NA,NA,NA,2,NA,NA,100,NA,75.188,"Biomass (µg C/L)","biomass","biom","SS",NA,NA,NA,NA,2,NA,NA,75,NA,56.675,"Biomass (µg C/L)",NA,NA,17.811,NA,12.594,2,0.571,NA,NA,NA
"671",671,703,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,84.586,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,75,NA,59.824,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,15.977,-0.886,1.098
"672",672,723,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,75.188,"Biomass (µg C/L)","biomass","biom","SS",NA,0,NA,0,2,NA,NA,50,NA,62.972,"Biomass (µg C/L)",2,NA,17.811,NA,12.594,2,0.571,12.594,-0.554,1.038
"673",673,743,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,84.586,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,50,NA,66.121,"Biomass (µg C/L)",2,NA,22.264,NA,15.743,2,0.571,22.208,-0.475,1.028
"674",674,762,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.985,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.193,2,NA,NA,50,NA,0.685,"Primary Productivity (µg C/L h)",1,NA,0.272,NA,0.192,2,0.571,0.273,-0.628,1.049
"675",675,779,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.546,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,2.778,"Primary Productivity (µg C/L h)",1,NA,0.752,NA,0.532,2,0.571,0.582,-0.754,1.071
"676",676,796,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.985,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.193,2,NA,NA,50,NA,0.622,"Primary Productivity (µg C/L h)",1,NA,0.273,NA,0.193,2,0.571,0.273,-0.758,1.072
"677",677,813,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",48,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.546,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,1.773,"Primary Productivity (µg C/L h)",1,NA,0.501,NA,0.355,2,0.571,0.426,-2.377,1.706
"678",678,684,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,100.251,"Biomass (µg C/L)","biomass","biom","SS",NA,26.583,NA,18.797,2,NA,NA,75,NA,110.202,"Biomass (µg C/L)",2,NA,40.075,NA,28.338,2,0.571,34.005,0.167,1.003
"679",679,704,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,184.837,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,75,NA,198.363,"Biomass (µg C/L)",2,NA,84.603,NA,59.824,2,0.571,61.84,0.125,1.002
"680",680,724,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,100.251,"Biomass (µg C/L)","biomass","biom","SS",NA,26.583,NA,18.797,2,NA,NA,50,NA,103.904,"Biomass (µg C/L)",2,NA,13.358,NA,9.446,2,0.571,21.037,0.099,1.001
"681",681,744,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,184.837,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,50,NA,132.242,"Biomass (µg C/L)",2,NA,62.339,NA,44.081,2,0.571,46.781,-0.642,1.052
"682",682,763,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.092,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.442,NA,0.312,2,NA,NA,50,NA,0.674,"Primary Productivity (µg C/L h)",1,NA,0.273,NA,0.193,2,0.571,0.367,-0.651,1.053
"683",683,780,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,5.91,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,1.672,NA,1.182,2,NA,NA,50,NA,4.196,"Primary Productivity (µg C/L h)",1,NA,0.084,NA,0.059,2,0.571,1.184,-0.828,1.086
"684",684,797,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.092,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.442,NA,0.312,2,NA,NA,50,NA,0.256,"Primary Productivity (µg C/L h)",1,NA,0.105,NA,0.074,2,0.571,0.321,-1.488,1.277
"685",685,814,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",51,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,5.91,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,1.672,NA,1.182,2,NA,NA,50,NA,2.896,"Primary Productivity (µg C/L h)",1,NA,0.418,NA,0.296,2,0.571,1.218,-1.414,1.25
"686",686,685,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,72.055,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,75,NA,207.809,"Biomass (µg C/L)",2,NA,35.623,NA,25.189,2,0.571,29.662,2.615,1.855
"687",687,705,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,454.261,"Biomass (µg C/L)","biomass","biom","SS",NA,31.013,NA,21.93,2,NA,NA,75,NA,324.307,"Biomass (µg C/L)",2,NA,146.943,NA,103.904,2,0.571,106.193,-0.699,1.061
"688",688,725,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,72.055,"Biomass (µg C/L)","biomass","biom","SS",NA,22.152,NA,15.664,2,NA,NA,50,NA,154.282,"Biomass (µg C/L)",2,NA,13.358,NA,9.446,2,0.571,18.292,2.569,1.825
"689",689,745,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,454.261,"Biomass (µg C/L)","biomass","biom","SS",NA,31.013,NA,21.93,2,NA,NA,50,NA,192.065,"Biomass (µg C/L)",2,NA,40.075,NA,28.338,2,0.571,35.832,-4.181,3.185
"690",690,764,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.27,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,1.112,NA,0.786,2,NA,NA,50,NA,1.734,"Primary Productivity (µg C/L h)",1,NA,0.776,NA,0.549,2,0.571,0.959,-0.32,1.013
"691",691,781,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,12.411,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.507,NA,1.773,2,NA,NA,50,NA,6.619,"Primary Productivity (µg C/L h)",1,NA,3.009,NA,2.128,2,0.571,2.77,-1.195,1.179
"692",692,798,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.27,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,1.112,NA,0.786,2,NA,NA,50,NA,0.605,"Primary Productivity (µg C/L h)",1,NA,0.273,NA,0.193,2,0.571,0.81,-1.176,1.173
"693",693,815,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",53,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,12.411,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.507,NA,1.773,2,NA,NA,50,NA,5.142,"Primary Productivity (µg C/L h)",1,NA,0.251,NA,0.177,2,0.571,1.782,-2.331,1.679
"694",694,686,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,288.221,"Biomass (µg C/L)","biomass","biom","SS",NA,212.664,NA,150.376,2,NA,NA,75,NA,321.159,"Biomass (µg C/L)",2,NA,8.906,NA,6.297,2,0.571,150.508,0.125,1.002
"695",695,706,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,673.559,"Biomass (µg C/L)","biomass","biom","SS",NA,181.65,NA,128.446,2,NA,NA,75,NA,384.131,"Biomass (µg C/L)",2,NA,97.962,NA,69.27,2,0.571,145.934,-1.133,1.161
"696",696,726,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,288.221,"Biomass (µg C/L)","biomass","biom","SS",NA,212.664,NA,150.376,2,NA,NA,50,NA,308.564,"Biomass (µg C/L)",2,NA,35.623,NA,25.189,2,0.571,152.471,0.076,1.001
"697",697,746,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,673.559,"Biomass (µg C/L)","biomass","biom","SS",NA,181.65,NA,128.446,2,NA,NA,50,NA,330.605,"Biomass (µg C/L)",2,NA,31.17,NA,22.04,2,0.571,130.323,-1.504,1.283
"698",698,765,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.33,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.609,NA,0.43,2,NA,NA,50,NA,3.623,"Primary Productivity (µg C/L h)",1,NA,1.111,NA,0.786,2,0.571,0.896,0.187,1.004
"699",699,782,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,15.78,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,18.137,NA,12.825,2,NA,NA,50,NA,9.988,"Primary Productivity (µg C/L h)",1,NA,0.585,NA,0.414,2,0.571,12.832,-0.258,1.008
"700",700,799,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.33,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.609,NA,0.43,2,NA,NA,50,NA,1.427,"Primary Productivity (µg C/L h)",1,NA,0.105,NA,0.074,2,0.571,0.437,-2.489,1.774
"701",701,816,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",55,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,15.78,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,18.137,NA,12.825,2,NA,NA,50,NA,7.092,"Primary Productivity (µg C/L h)",1,NA,1.337,NA,0.946,2,0.571,12.86,-0.386,1.019
"702",702,687,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,541.98,"Biomass (µg C/L)","biomass","biom","SS",NA,261.399,NA,184.837,2,NA,NA,75,NA,604.534,"Biomass (µg C/L)",2,NA,80.151,NA,56.675,2,0.571,193.331,0.185,1.004
"703",703,707,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1162.281,"Biomass (µg C/L)","biomass","biom","SS",NA,128.484,NA,90.852,2,NA,NA,75,NA,629.723,"Biomass (µg C/L)",2,NA,17.811,NA,12.594,2,0.571,91.721,-3.318,2.376
"704",704,727,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,541.98,"Biomass (µg C/L)","biomass","biom","SS",NA,261.399,NA,184.837,2,NA,NA,50,NA,403.023,"Biomass (µg C/L)",2,NA,8.906,NA,6.297,2,0.571,184.944,-0.429,1.023
"705",705,747,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1162.281,"Biomass (µg C/L)","biomass","biom","SS",NA,128.484,NA,90.852,2,NA,NA,50,NA,324.307,"Biomass (µg C/L)",2,NA,75.698,NA,53.526,2,0.571,105.448,-4.541,3.578
"706",706,766,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,11.377,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.954,NA,2.089,2,NA,NA,50,NA,12.853,"Primary Productivity (µg C/L h)",1,NA,3.457,NA,2.445,2,0.571,3.216,0.262,1.009
"707",707,783,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,33.806,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,9.027,NA,6.383,2,NA,NA,50,NA,25.059,"Primary Productivity (µg C/L h)",1,NA,1.672,NA,1.182,2,0.571,6.492,-0.77,1.074
"708",708,800,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,11.377,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.954,NA,2.089,2,NA,NA,50,NA,6.867,"Primary Productivity (µg C/L h)",1,NA,4.462,NA,3.155,2,0.571,3.784,-0.681,1.058
"709",709,817,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",58,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,33.806,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,9.027,NA,6.383,2,NA,NA,50,NA,15.662,"Primary Productivity (µg C/L h)",1,NA,3.594,NA,2.541,2,0.571,6.87,-1.509,1.285
"710",710,688,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1127.82,"Biomass (µg C/L)","biomass","biom","SS",NA,168.359,NA,119.048,2,NA,NA,75,NA,1042.191,"Biomass (µg C/L)",2,NA,235.999,NA,166.877,2,0.571,204.988,-0.239,1.007
"711",711,708,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,870.927,"Biomass (µg C/L)","biomass","biom","SS",NA,177.22,NA,125.313,2,NA,NA,75,NA,1045.34,"Biomass (µg C/L)",2,NA,89.056,NA,62.972,2,0.571,140.246,0.711,1.063
"712",712,728,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1127.82,"Biomass (µg C/L)","biomass","biom","SS",NA,168.359,NA,119.048,2,NA,NA,50,NA,743.073,"Biomass (µg C/L)",2,NA,44.528,NA,31.486,2,0.571,123.141,-1.785,1.398
"713",713,748,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,870.927,"Biomass (µg C/L)","biomass","biom","SS",NA,177.22,NA,125.313,2,NA,NA,50,NA,617.128,"Biomass (µg C/L)",2,NA,71.245,NA,50.378,2,0.571,135.061,-1.074,1.144
"714",714,767,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,24.403,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,27.419,NA,19.388,2,NA,NA,50,NA,23.392,"Primary Productivity (µg C/L h)",1,NA,29.094,NA,20.572,2,0.571,28.269,-0.02,1
"715",715,784,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,43.853,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,21.23,NA,15.012,2,NA,NA,50,NA,34.456,"Primary Productivity (µg C/L h)",1,NA,2.758,NA,1.95,2,0.571,15.138,-0.355,1.016
"716",716,801,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,24.403,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,27.419,NA,19.388,2,NA,NA,50,NA,22.5,"Primary Productivity (µg C/L h)",1,NA,11.834,NA,8.368,2,0.571,21.117,-0.051,1
"717",717,818,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",60,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,43.853,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,21.23,NA,15.012,2,NA,NA,50,NA,19.09,"Primary Productivity (µg C/L h)",1,NA,11.785,NA,8.333,2,0.571,17.17,-0.824,1.085
"718",718,689,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2380.952,"Biomass (µg C/L)","biomass","biom","SS",NA,106.332,NA,75.188,2,NA,NA,75,NA,1423.174,"Biomass (µg C/L)",2,NA,106.868,NA,75.567,2,0.571,106.6,-5.134,4.295
"719",719,709,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,758.145,"Biomass (µg C/L)","biomass","biom","SS",NA,248.108,NA,175.439,2,NA,NA,75,NA,856.423,"Biomass (µg C/L)",2,NA,115.773,NA,81.864,2,0.571,193.599,0.29,1.011
"720",720,729,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2380.952,"Biomass (µg C/L)","biomass","biom","SS",NA,106.332,NA,75.188,2,NA,NA,50,NA,1322.418,"Biomass (µg C/L)",2,NA,195.924,NA,138.539,2,0.571,157.627,-3.837,2.841
"721",721,749,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,758.145,"Biomass (µg C/L)","biomass","biom","SS",NA,248.108,NA,175.439,2,NA,NA,50,NA,846.977,"Biomass (µg C/L)",2,NA,129.132,NA,91.31,2,0.571,197.778,0.257,1.008
"722",722,768,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,37.31,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,10.83,NA,7.658,2,NA,NA,50,NA,26.939,"Primary Productivity (µg C/L h)",1,NA,0.608,NA,0.43,2,0.571,7.67,-0.773,1.075
"723",723,785,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,15.012,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,5.182,NA,3.664,2,NA,NA,50,NA,17.317,"Primary Productivity (µg C/L h)",1,NA,2.925,NA,2.069,2,0.571,4.208,0.313,1.012
"724",724,802,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,37.31,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,10.83,NA,7.658,2,NA,NA,50,NA,20.953,"Primary Productivity (µg C/L h)",1,NA,7.31,NA,5.169,2,0.571,9.239,-1.012,1.128
"725",725,819,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",62,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,15.012,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,5.182,NA,3.664,2,NA,NA,50,NA,22.045,"Primary Productivity (µg C/L h)",1,NA,12.621,NA,8.924,2,0.571,9.647,0.417,1.022
"726",726,690,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1741.855,"Biomass (µg C/L)","biomass","biom","SS",NA,265.83,NA,187.97,2,NA,NA,75,NA,1712.846,"Biomass (µg C/L)",2,NA,249.358,NA,176.322,2,0.571,257.725,-0.064,1.001
"727",727,710,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,466.792,"Biomass (µg C/L)","biomass","biom","SS",NA,190.511,NA,134.712,2,NA,NA,75,NA,425.063,"Biomass (µg C/L)",2,NA,75.698,NA,53.526,2,0.571,144.956,-0.164,1.003
"728",728,730,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1741.855,"Biomass (µg C/L)","biomass","biom","SS",NA,265.83,NA,187.97,2,NA,NA,50,NA,1536.524,"Biomass (µg C/L)",2,NA,89.056,NA,62.972,2,0.571,198.238,-0.592,1.044
"729",729,750,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,466.792,"Biomass (µg C/L)","biomass","biom","SS",NA,190.511,NA,134.712,2,NA,NA,50,NA,532.116,"Biomass (µg C/L)",2,NA,57.887,NA,40.932,2,0.571,140.793,0.265,1.009
"730",730,769,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,26.518,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,5.971,NA,4.222,2,NA,NA,50,NA,30.128,"Primary Productivity (µg C/L h)",1,NA,4.797,NA,3.392,2,0.571,5.416,0.381,1.018
"731",731,786,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,6.147,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.34,NA,1.655,2,NA,NA,50,NA,10.165,"Primary Productivity (µg C/L h)",1,NA,0.836,NA,0.591,2,0.571,1.757,1.307,1.214
"732",732,803,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,26.518,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,5.971,NA,4.222,2,NA,NA,50,NA,33.739,"Primary Productivity (µg C/L h)",1,NA,7.31,NA,5.169,2,0.571,6.674,0.618,1.048
"733",733,820,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",65,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,6.147,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.34,NA,1.655,2,NA,NA,50,NA,16.903,"Primary Productivity (µg C/L h)",1,NA,7.355,NA,5.201,2,0.571,5.458,1.126,1.159
"734",734,691,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1196.742,"Biomass (µg C/L)","biomass","biom","SS",NA,230.386,NA,162.907,2,NA,NA,75,NA,1032.746,"Biomass (µg C/L)",2,NA,160.301,NA,113.35,2,0.571,198.462,-0.472,1.028
"735",735,711,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,451.128,"Biomass (µg C/L)","biomass","biom","SS",NA,106.332,NA,75.188,2,NA,NA,75,NA,314.861,"Biomass (µg C/L)",2,NA,53.434,NA,37.783,2,0.571,84.148,-0.925,1.107
"736",736,731,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1196.742,"Biomass (µg C/L)","biomass","biom","SS",NA,230.386,NA,162.907,2,NA,NA,50,NA,1498.741,"Biomass (µg C/L)",2,NA,106.868,NA,75.567,2,0.571,179.58,0.961,1.115
"737",737,751,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,451.128,"Biomass (µg C/L)","biomass","biom","SS",NA,106.332,NA,75.188,2,NA,NA,50,NA,604.534,"Biomass (µg C/L)",2,NA,80.151,NA,56.675,2,0.571,94.156,0.931,1.108
"738",738,770,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,13.241,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.619,NA,1.852,2,NA,NA,50,NA,9.86,"Primary Productivity (µg C/L h)",1,NA,0.609,NA,0.43,2,0.571,1.901,-1.016,1.129
"739",739,787,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.896,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.919,NA,0.65,2,NA,NA,50,NA,3.191,"Primary Productivity (µg C/L h)",1,NA,0.167,NA,0.118,2,0.571,0.661,0.256,1.008
"740",740,804,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,13.241,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,2.619,NA,1.852,2,NA,NA,50,NA,10.627,"Primary Productivity (µg C/L h)",1,NA,0.105,NA,0.074,2,0.571,1.853,-0.806,1.081
"741",741,821,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",67,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.896,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.919,NA,0.65,2,NA,NA,50,NA,3.901,"Primary Productivity (µg C/L h)",1,NA,0.836,NA,0.591,2,0.571,0.879,0.653,1.053
"742",742,692,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,836.466,"Biomass (µg C/L)","biomass","biom","SS",NA,110.762,NA,78.321,2,NA,NA,75,NA,909.95,"Biomass (µg C/L)",2,NA,57.887,NA,40.932,2,0.571,88.372,0.475,1.028
"743",743,712,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,307.018,"Biomass (µg C/L)","biomass","biom","SS",NA,44.305,NA,31.328,2,NA,NA,75,NA,258.186,"Biomass (µg C/L)",2,NA,53.434,NA,37.783,2,0.571,49.082,-0.569,1.04
"744",744,732,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,836.466,"Biomass (µg C/L)","biomass","biom","SS",NA,110.762,NA,78.321,2,NA,NA,50,NA,1010.705,"Biomass (µg C/L)",2,NA,40.075,NA,28.338,2,0.571,83.29,1.195,1.179
"745",745,752,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,307.018,"Biomass (µg C/L)","biomass","biom","SS",NA,44.305,NA,31.328,2,NA,NA,50,NA,538.413,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,31.486,4.199,3.204
"746",746,771,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,15.248,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,10.829,NA,7.658,2,NA,NA,50,NA,15.896,"Primary Productivity (µg C/L h)",1,NA,3.792,NA,2.682,2,0.571,8.114,0.046,1
"747",747,788,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.364,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,3.014,"Primary Productivity (µg C/L h)",1,NA,0.418,NA,0.296,2,0.571,0.378,0.982,1.12
"748",748,805,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,15.248,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,10.829,NA,7.658,2,NA,NA,50,NA,16.663,"Primary Productivity (µg C/L h)",1,NA,0.608,NA,0.43,2,0.571,7.67,0.105,1.001
"749",749,822,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",69,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.364,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,6.147,"Primary Productivity (µg C/L h)",1,NA,3.176,NA,2.246,2,0.571,2.258,0.957,1.115
"750",750,693,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,833.333,"Biomass (µg C/L)","biomass","biom","SS",NA,115.193,NA,81.454,2,NA,NA,75,NA,771.411,"Biomass (µg C/L)",2,NA,84.603,NA,59.824,2,0.571,101.062,-0.35,1.015
"751",751,713,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,187.97,"Biomass (µg C/L)","biomass","biom","SS",NA,35.444,NA,25.063,2,NA,NA,75,NA,141.688,"Biomass (µg C/L)",2,NA,93.509,NA,66.121,2,0.571,70.711,-0.374,1.017
"752",752,733,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,833.333,"Biomass (µg C/L)","biomass","biom","SS",NA,115.193,NA,81.454,2,NA,NA,50,NA,1146.096,"Biomass (µg C/L)",2,NA,71.245,NA,50.378,2,0.571,95.774,1.866,1.435
"753",753,753,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,187.97,"Biomass (µg C/L)","biomass","biom","SS",NA,35.444,NA,25.063,2,NA,NA,50,NA,355.793,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,25.26,3.797,2.802
"754",754,772,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,7.536,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.193,2,NA,NA,50,NA,3.682,"Primary Productivity (µg C/L h)",1,NA,0.273,NA,0.193,2,0.571,0.273,-8.064,9.128
"755",755,789,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.123,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.585,NA,0.414,2,NA,NA,50,NA,0.827,"Primary Productivity (µg C/L h)",1,NA,0.167,NA,0.118,2,0.571,0.43,-0.392,1.019
"756",756,806,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,7.536,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.193,2,NA,NA,50,NA,4.212,"Primary Productivity (µg C/L h)",1,NA,0.105,NA,0.074,2,0.571,0.207,-9.163,11.495
"757",757,823,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",72,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.123,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.585,NA,0.414,2,NA,NA,50,NA,1.655,"Primary Productivity (µg C/L h)",1,NA,0.669,NA,0.473,2,0.571,0.628,0.484,1.029
"758",758,694,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,695.489,"Biomass (µg C/L)","biomass","biom","SS",NA,70.888,NA,50.125,2,NA,NA,75,NA,601.385,"Biomass (µg C/L)",2,NA,93.509,NA,66.121,2,0.571,82.973,-0.648,1.053
"759",759,714,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,134.712,"Biomass (µg C/L)","biomass","biom","SS",NA,39.874,NA,28.195,2,NA,NA,75,NA,75.567,"Biomass (µg C/L)",2,NA,53.434,NA,37.783,2,0.571,47.144,-0.717,1.064
"760",760,734,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,695.489,"Biomass (µg C/L)","biomass","biom","SS",NA,70.888,NA,50.125,2,NA,NA,50,NA,944.584,"Biomass (µg C/L)",2,NA,80.151,NA,56.675,2,0.571,75.661,1.881,1.442
"761",761,754,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,134.712,"Biomass (µg C/L)","biomass","biom","SS",NA,39.874,NA,28.195,2,NA,NA,50,NA,239.295,"Biomass (µg C/L)",2,NA,17.811,NA,12.594,2,0.571,30.881,1.935,1.468
"762",762,773,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.79,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.193,2,NA,NA,50,NA,1.068,"Primary Productivity (µg C/L h)",1,NA,0.608,NA,0.43,2,0.571,0.471,-2.088,1.545
"763",763,790,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.414,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.251,NA,0.177,2,NA,NA,50,NA,0.414,"Primary Productivity (µg C/L h)",1,NA,0.084,NA,0.059,2,0.571,0.187,0,1
"764",764,807,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.79,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.193,2,NA,NA,50,NA,1.243,"Primary Productivity (µg C/L h)",1,NA,0.273,NA,0.193,2,0.571,0.273,-3.235,2.308
"765",765,824,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",74,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.414,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.251,NA,0.177,2,NA,NA,50,NA,0.768,"Primary Productivity (µg C/L h)",1,NA,0.084,NA,0.059,2,0.571,0.187,1.084,1.147
"766",766,695,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,670.426,"Biomass (µg C/L)","biomass","biom","SS",NA,79.749,NA,56.391,2,NA,NA,75,NA,513.224,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,56.479,-1.591,1.316
"767",767,715,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,59.524,"Biomass (µg C/L)","biomass","biom","SS",NA,31.013,NA,21.93,2,NA,NA,75,NA,56.675,"Biomass (µg C/L)",2,NA,62.339,NA,44.081,2,0.571,49.234,-0.033,1
"768",768,735,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,670.426,"Biomass (µg C/L)","biomass","biom","SS",NA,79.749,NA,56.391,2,NA,NA,50,NA,563.602,"Biomass (µg C/L)",2,NA,57.887,NA,40.932,2,0.571,69.68,-0.876,1.096
"769",769,755,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,59.524,"Biomass (µg C/L)","biomass","biom","SS",NA,31.013,NA,21.93,2,NA,NA,50,NA,176.322,"Biomass (µg C/L)",2,NA,44.528,NA,31.486,2,0.571,38.37,1.739,1.378
"770",770,774,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.783,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.609,NA,0.43,2,NA,NA,50,NA,0.943,"Primary Productivity (µg C/L h)",1,NA,0.441,NA,0.312,2,0.571,0.531,-1.978,1.489
"771",771,791,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.473,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.167,NA,0.118,2,NA,NA,50,NA,0.473,"Primary Productivity (µg C/L h)",1,NA,0,NA,0,2,0.571,0.118,0,1
"772",772,808,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,2.783,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.609,NA,0.43,2,NA,NA,50,NA,1.236,"Primary Productivity (µg C/L h)",1,NA,0.273,NA,0.193,2,0.571,0.472,-1.874,1.439
"773",773,825,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",76,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.473,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.167,NA,0.118,2,NA,NA,50,NA,0.709,"Primary Productivity (µg C/L h)",1,NA,0,NA,0,2,0.571,0.118,1.143,1.163
"774",774,696,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,438.596,"Biomass (µg C/L)","biomass","biom","SS",NA,106.332,NA,75.188,2,NA,NA,75,NA,358.942,"Biomass (µg C/L)",2,NA,44.528,NA,31.486,2,0.571,81.514,-0.558,1.039
"775",775,716,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,18.797,"Biomass (µg C/L)","biomass","biom","SS",NA,8.861,NA,6.266,2,NA,NA,75,NA,12.594,"Biomass (µg C/L)",2,NA,0,NA,0,2,0.571,6.266,-0.566,1.04
"776",776,736,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,438.596,"Biomass (µg C/L)","biomass","biom","SS",NA,106.332,NA,75.188,2,NA,NA,50,NA,698.992,"Biomass (µg C/L)",2,NA,106.868,NA,75.567,2,0.571,106.6,1.396,1.244
"777",777,756,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,18.797,"Biomass (µg C/L)","biomass","biom","SS",NA,8.861,NA,6.266,2,NA,NA,50,NA,88.161,"Biomass (µg C/L)",2,NA,8.906,NA,6.297,2,0.571,8.883,4.462,3.489
"778",778,775,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.469,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.106,NA,0.075,2,NA,NA,50,NA,0.103,"Primary Productivity (µg C/L h)",1,NA,0.274,NA,0.193,2,0.571,0.207,-3.766,2.772
"779",779,792,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.355,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,0.177,"Primary Productivity (µg C/L h)",1,NA,0.084,NA,0.059,2,0.571,0.244,-0.416,1.022
"780",780,809,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.469,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.106,NA,0.075,2,NA,NA,50,NA,0.16,"Primary Productivity (µg C/L h)",1,NA,0.106,NA,0.075,2,0.571,0.106,-7.087,7.279
"781",781,826,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",79,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.355,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,0.591,"Primary Productivity (µg C/L h)",1,NA,0.167,NA,0.118,2,0.571,0.264,0.511,1.033
"782",782,697,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,272.556,"Biomass (µg C/L)","biomass","biom","SS",NA,48.735,NA,34.461,2,NA,NA,75,NA,302.267,"Biomass (µg C/L)",2,NA,80.151,NA,56.675,2,0.571,66.33,0.256,1.008
"783",783,717,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)","No STD or STE available","Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,NA,NA,NA,2,NA,NA,100,NA,6.266,"Biomass (µg C/L)","biomass","biom","SS",NA,0,NA,0,2,NA,NA,75,NA,6.297,"Biomass (µg C/L)",NA,NA,0,NA,0,2,0.571,NA,NA,NA
"784",784,737,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,272.556,"Biomass (µg C/L)","biomass","biom","SS",NA,48.735,NA,34.461,2,NA,NA,50,NA,528.967,"Biomass (µg C/L)",2,NA,35.623,NA,25.189,2,0.571,42.686,3.433,2.473
"785",785,757,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,6.266,"Biomass (µg C/L)","biomass","biom","SS",NA,0,NA,0,2,NA,NA,50,NA,15.743,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,3.149,1.72,1.37
"786",786,776,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.818,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.273,NA,0.193,2,NA,NA,50,NA,0.036,"Primary Productivity (µg C/L h)",1,NA,0.19,NA,0.134,2,0.571,0.235,-4.33,3.344
"787",787,793,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.355,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,0.296,"Primary Productivity (µg C/L h)",1,NA,0.251,NA,0.177,2,0.571,0.296,-0.114,1.002
"788",788,810,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,1.818,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.273,NA,0.193,2,NA,NA,50,NA,-0.084,"Primary Productivity (µg C/L h)",1,NA,0.441,NA,0.312,2,0.571,0.367,-2.963,2.097
"789",789,827,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",81,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.355,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.334,NA,0.236,2,NA,NA,50,NA,0.65,"Primary Productivity (µg C/L h)",1,NA,0.084,NA,0.059,2,0.571,0.244,0.693,1.06
"790",790,698,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,441.729,"Biomass (µg C/L)","biomass","biom","SS",NA,163.928,NA,115.915,2,NA,NA,75,NA,144.836,"Biomass (µg C/L)",2,NA,89.056,NA,62.972,2,0.571,131.916,-1.286,1.207
"791",791,718,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.133,"Biomass (µg C/L)","biomass","biom","SS",NA,4.43,NA,3.133,2,NA,NA,75,NA,0,"Biomass (µg C/L)",2,NA,0,NA,0,2,0.571,3.133,-0.571,1.041
"792",792,738,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,441.729,"Biomass (µg C/L)","biomass","biom","SS",NA,163.928,NA,115.915,2,NA,NA,50,NA,349.496,"Biomass (µg C/L)",2,NA,48.981,NA,34.635,2,0.571,120.979,-0.436,1.024
"793",793,758,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.133,"Biomass (µg C/L)","biomass","biom","SS",NA,4.43,NA,3.133,2,NA,NA,50,NA,18.892,"Biomass (µg C/L)",2,NA,0,NA,0,2,0.571,3.133,2.874,2.033
"794",794,777,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.745,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.441,NA,0.312,2,NA,NA,50,NA,-0.15,"Primary Productivity (µg C/L h)",1,NA,0.274,NA,0.194,2,0.571,0.367,-1.393,1.243
"795",795,794,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.532,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.251,NA,0.177,2,NA,NA,50,NA,0.118,"Primary Productivity (µg C/L h)",1,NA,0,NA,0,2,0.571,0.177,-1.333,1.222
"796",796,811,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.745,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.441,NA,0.312,2,NA,NA,50,NA,-0.448,"Primary Productivity (µg C/L h)",1,NA,0.611,NA,0.432,2,0.571,0.533,-1.28,1.205
"797",797,828,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",83,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.532,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.251,NA,0.177,2,NA,NA,50,NA,0.473,"Primary Productivity (µg C/L h)",1,NA,0,NA,0,2,0.571,0.177,-0.19,1.005
"798",798,699,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,266.291,"Biomass (µg C/L)","biomass","biom","SS",NA,31.013,NA,21.93,2,NA,NA,75,NA,81.864,"Biomass (µg C/L)",2,NA,35.623,NA,25.189,2,0.571,33.398,-3.156,2.245
"799",799,719,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,9.398,"Biomass (µg C/L)","biomass","biom","SS",NA,4.43,NA,3.133,2,NA,NA,75,NA,-3.149,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,4.442,-1.614,1.326
"800",800,739,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,266.291,"Biomass (µg C/L)","biomass","biom","SS",NA,31.013,NA,21.93,2,NA,NA,50,NA,327.456,"Biomass (µg C/L)",2,NA,26.717,NA,18.892,2,0.571,28.945,1.208,1.182
"801",801,759,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,9.398,"Biomass (µg C/L)","biomass","biom","SS",NA,4.43,NA,3.133,2,NA,NA,50,NA,12.594,"Biomass (µg C/L)",2,NA,8.906,NA,6.297,2,0.571,7.033,0.26,1.008
"802",802,778,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.379,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.194,2,NA,NA,50,NA,-0.279,"Primary Productivity (µg C/L h)",1,NA,0.105,NA,0.074,2,0.571,0.208,-1.809,1.409
"803",803,795,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.177,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.084,NA,0.059,2,NA,NA,50,NA,0.177,"Primary Productivity (µg C/L h)",1,NA,0.084,NA,0.059,2,0.571,0.084,0,1
"804",804,812,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.379,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.274,NA,0.194,2,NA,NA,50,NA,-0.577,"Primary Productivity (µg C/L h)",1,NA,0.106,NA,0.075,2,0.571,0.208,-2.628,1.863
"805",805,829,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 3",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",86,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,0.177,"Primary Productivity (µg C/L h)","area-specific production","biom","dSS",NA,0.084,NA,0.059,2,NA,NA,50,NA,0,"Primary Productivity (µg C/L h)",1,NA,0,NA,0,2,0.571,0.059,-1.714,1.367
"806",806,700,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",88,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,137.845,"Biomass (µg C/L)","biomass","biom","SS",NA,26.583,NA,18.797,2,NA,NA,75,NA,53.526,"Biomass (µg C/L)",2,NA,13.358,NA,9.446,2,0.571,21.037,-2.29,1.656
"807",807,720,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)","No STD or STE available","Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",88,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,NA,NA,NA,2,NA,NA,100,NA,6.266,"Biomass (µg C/L)","biomass","biom","SS",NA,0,NA,0,2,NA,NA,75,NA,0,"Biomass (µg C/L)",NA,NA,0,NA,0,2,0.571,NA,NA,NA
"808",808,740,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",88,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,137.845,"Biomass (µg C/L)","biomass","biom","SS",NA,26.583,NA,18.797,2,NA,NA,50,NA,176.322,"Biomass (µg C/L)",2,NA,8.906,NA,6.297,2,0.571,19.824,1.109,1.154
"809",809,760,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",88,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,6.266,"Biomass (µg C/L)","biomass","biom","SS",NA,0,NA,0,2,NA,NA,50,NA,3.149,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,3.149,-0.566,1.04
"810",810,701,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",95,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,62.657,"Biomass (µg C/L)","biomass","biom","SS",NA,35.444,NA,25.063,2,NA,NA,75,NA,18.892,"Biomass (µg C/L)",2,NA,0,NA,0,2,0.571,25.063,-0.998,1.124
"811",811,721,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",95,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.133,"Biomass (µg C/L)","biomass","biom","SS",NA,4.43,NA,3.133,2,NA,NA,75,NA,6.297,"Biomass (µg C/L)",2,NA,0,NA,0,2,0.571,3.133,0.577,1.042
"812",812,741,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",95,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,0,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,62.657,"Biomass (µg C/L)","biomass","biom","SS",NA,35.444,NA,25.063,2,NA,NA,50,NA,97.607,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,25.26,0.791,1.078
"813",813,761,"291","Lewandowska, A; Sommer, U",2010,"Climate change and the spring bloom: a mesocosm study on the influence of light and temperature on phytoplankton and mesozooplankton","MARINE ECOLOGY PROGRESS SERIES",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2010","Lab","coastal",54.52,10.38,"Kiel Bight, Germany","Total phytoplankton","phytoplankton",95,"mesocosm","tank",1400,NA,"yes","none","reduced light","Natural",NA,NA,6,NA,NA,NA,0.9,14.7,0.9,14.7,NA,4,NA,NA,100,NA,3.133,"Biomass (µg C/L)","biomass","biom","SS",NA,4.43,NA,3.133,2,NA,NA,50,NA,9.446,"Biomass (µg C/L)",2,NA,4.453,NA,3.149,2,0.571,4.442,0.812,1.082
"814",814,830,"293","de los Santos, CB; Brun, FG; Bouma, TJ; Vergara, JJ; Perez-Llorens, JL",2010,"Acclimation of seagrass Zostera noltii to co-occurring hydrodynamic and light stresses","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 2","spring","2010","Lab","coastal",36.5,-6.17,"Cádiz, Spain","Zostera noltii (apical shoot)","seagrass",46,"mesocosm","tank",NA,NA,"unknown","current","reduced light","18",NA,NA,19.5,NA,NA,30,0.22,2.03,0.22,2.03,NA,4,NA,NA,100,NA,1.576,"Growth rate (mg freshweight day-1)","growth rate","biom","dSS",NA,1.09,NA,0.443,6,NA,NA,16,NA,-0.639,"Growth rate (mg freshweight day-1)",2,NA,2.48,NA,1.013,6,0.923,1.914,-1.068,0.381
"815",815,831,"293","de los Santos, CB; Brun, FG; Bouma, TJ; Vergara, JJ; Perez-Llorens, JL",2010,"Acclimation of seagrass Zostera noltii to co-occurring hydrodynamic and light stresses","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 2","spring","2010","Lab","coastal",36.5,-6.17,"Cádiz, Spain","Zostera noltii (apical shoot)","seagrass",46,"mesocosm","tank",NA,NA,"unknown","current","reduced light","18",NA,NA,19.5,NA,NA,30,0.22,2.03,0.22,2.03,NA,4,NA,NA,100,NA,2.462,"Growth rate (mg freshweight day-1)","growth rate","biom","dSS",NA,1.09,NA,0.443,6,NA,NA,16,NA,-1.399,"Growth rate (mg freshweight day-1)",2,NA,2.48,NA,1.013,6,0.923,1.914,-1.861,0.478
"816",816,832,"293","de los Santos, CB; Brun, FG; Bouma, TJ; Vergara, JJ; Perez-Llorens, JL",2010,"Acclimation of seagrass Zostera noltii to co-occurring hydrodynamic and light stresses","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 2","spring","2010","Lab","coastal",36.5,-6.17,"Cádiz, Spain","Zostera noltii (apical shoot)","seagrass",46,"mesocosm","tank",NA,NA,"unknown","current","reduced light","18",NA,NA,19.5,NA,NA,30,0.22,2.03,0.22,2.03,NA,4,NA,NA,100,NA,2.905,"Growth rate (mg freshweight day-1)","growth rate","biom","dSS",NA,1.09,NA,0.443,6,NA,NA,16,NA,1.829,"Growth rate (mg freshweight day-1)",2,NA,2.636,NA,1.076,6,0.923,2.015,-0.493,0.343
"817",817,833,"293","de los Santos, CB; Brun, FG; Bouma, TJ; Vergara, JJ; Perez-Llorens, JL",2010,"Acclimation of seagrass Zostera noltii to co-occurring hydrodynamic and light stresses","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 2","spring","2010","Lab","coastal",36.5,-6.17,"Cádiz, Spain","Zostera noltii (single shoot)","seagrass",46,"mesocosm","tank",NA,NA,"unknown","current","reduced light","18",NA,NA,19.5,NA,NA,30,0.22,2.03,0.22,2.03,NA,4,NA,NA,100,NA,0.816,"Growth rate (mg freshweight day-1)","growth rate","biom","dSS",NA,0.54,NA,0.222,6,NA,NA,16,NA,-0.449,"Growth rate (mg freshweight day-1)",2,NA,0.543,NA,0.222,6,0.923,0.543,-2.153,0.527
"818",818,834,"293","de los Santos, CB; Brun, FG; Bouma, TJ; Vergara, JJ; Perez-Llorens, JL",2010,"Acclimation of seagrass Zostera noltii to co-occurring hydrodynamic and light stresses","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 2","spring","2010","Lab","coastal",36.5,-6.17,"Cádiz, Spain","Zostera noltii (single shoot)","seagrass",46,"mesocosm","tank",NA,NA,"unknown","current","reduced light","18",NA,NA,19.5,NA,NA,30,0.22,2.03,0.22,2.03,NA,4,NA,NA,100,NA,1.259,"Growth rate (mg freshweight day-1)","growth rate","biom","dSS",NA,0.23,NA,0.095,6,NA,NA,16,NA,0.12,"Growth rate (mg freshweight day-1)",2,NA,0.62,NA,0.253,6,0.923,0.468,-2.246,0.543
"819",819,835,"293","de los Santos, CB; Brun, FG; Bouma, TJ; Vergara, JJ; Perez-Llorens, JL",2010,"Acclimation of seagrass Zostera noltii to co-occurring hydrodynamic and light stresses","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 2","spring","2010","Lab","coastal",36.5,-6.17,"Cádiz, Spain","Zostera noltii (single shoot)","seagrass",46,"mesocosm","tank",NA,NA,"unknown","current","reduced light","18",NA,NA,19.5,NA,NA,30,0.22,2.03,0.22,2.03,NA,4,NA,NA,100,NA,1.07,"Growth rate (mg freshweight day-1)","growth rate","biom","dSS",NA,0.31,NA,0.127,6,NA,NA,16,NA,0.31,"Growth rate (mg freshweight day-1)",2,NA,0.698,NA,0.285,6,0.923,0.54,-1.299,0.404
"820",820,836,"302","Carvalho, AP; Monteiro, CM; Malcata, FX",2009,"Simultaneous effect of irradiance and temperature on biochemical composition of the microalga Pavlova lutheri","JOURNAL OF APPLIED PHYCOLOGY",1,NA,"Data are given in 3D bar plots, and are only data per cell",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"821",821,837,"318","Estrada, M; Bayer-Giraldi, M; Felipe, J; Marrase, C; Sala, MM; Vidal, M",2009,"Light and nutrient effects on microbial communities collected during spring and summer in the Beaufort Sea","AQUATIC MICROBIAL ECOLOGY",1,NA,"no replicates",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"822",822,838,"320","Borghini, F; Colacevich, A; Bergamino, N; Micarelli, P; Dattilo, AM; Focardi, S; Focardi, S; Loiselle, SA",2009,"The microalgae Tetraselmis suecica in mesocosms under different light regimes","CHEMISTRY AND ECOLOGY",1,NA,"no replicates, no usable light intensity measures given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"823",823,839,"332","Cymbola, J; Ogdahl, M; Steinman, AD",2008,"Phytoplankton response to light and internal phosphorus loading from sediment release","FRESHWATER BIOLOGY",1,NA,"Freshwater species",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"824",824,840,"334","Terrado, R; Lovejoy, C; Massana, R; Vincent, WF",2008,"Microbial food web responses to light and nutrients beneath the coastal Arctic Ocean sea ice during the winter-spring transition","JOURNAL OF MARINE SYSTEMS",1,NA,"no different light intensities used",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"825",825,841,"339","Thom, RM; Southard, SL; Borde, AB; Stoltz, P",2008,"Light requirements for growth and survival of eelgrass (Zostera marina L.) in Pacific Northwest (USA) estuaries","ESTUARIES AND COASTS",1,"seagrass","no or only average value for standard deviation is given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"826",826,842,"352","Leoni, V; Vela, A; Pasqualini, V; Pergent-Martini, C; Pergent, G",2008,"Effects of experimental reduction of light and nutrient enrichments (N and P) on seagrasses: a review","AQUATIC CONSERVATION-MARINE AND FRESHWATER ECOSYSTEMS",1,"seagrass","no data, only review",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"827",827,843,"363","Dubbs, LL; Whalen, SC",2008,"Light-Nutrient Influences on Biomass, Photosynthetic Potential and Composition of Suspended Algal Assemblages in the Middle Cape Fear River, USA","INTERNATIONAL REVIEW OF HYDROBIOLOGY",1,NA,"Freshwater species",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"828",828,844,"364","Carroll, J; Gobler, CJ; Peterson, BJ",2008,"Resource-restricted growth of eelgrass in New York estuaries: light limitation, and alleviation of nutrient stress by hard clams","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 5",NA,"2008","Field","coastal",40.84,-72.52,"Long Island, New York","Zostera marina","seagrass",35,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,4.583,"Leaves per shoot","abundance","biom","SS",NA,1.1,NA,0.201,30,NA,NA,60,NA,2.606,"Leaves per shoot",2,NA,1.293,NA,0.236,30,0.987,1.201,-1.624,0.089
"829",829,845,"364","Carroll, J; Gobler, CJ; Peterson, BJ",2008,"Resource-restricted growth of eelgrass in New York estuaries: light limitation, and alleviation of nutrient stress by hard clams","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 5",NA,"2008","Field","coastal",40.84,-72.52,"Long Island, New York","Zostera marina","seagrass",35,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,45.397,"Total leaf area (cm2)","biomass","biom","SS",NA,21.08,NA,3.848,30,NA,NA,60,NA,20.392,"Total leaf area (cm2)",2,NA,11.495,NA,2.099,30,0.987,16.977,-1.454,0.084
"830",830,846,"364","Carroll, J; Gobler, CJ; Peterson, BJ",2008,"Resource-restricted growth of eelgrass in New York estuaries: light limitation, and alleviation of nutrient stress by hard clams","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass",NA,"Fig 5",NA,"2008","Field","coastal",40.84,-72.52,"Long Island, New York","Zostera marina","seagrass",35,"field plot","no container",NA,NA,"unknown","none","shading screen","natural",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.841,"Productivity (cm2 shoot-1 d-1)","mass-specific production","phys","dQ",NA,0.17,NA,0.032,30,NA,NA,60,NA,0.56,"Productivity (cm2 shoot-1 d-1)",1,NA,0.29,NA,0.053,30,0.987,0.239,-1.158,0.078
"831",831,847,"380","Olive, I; Brun, FG; Vergara, JJ; Perez-Llorens, JL",2007,"Effects of light and Biomass partitioning on growth, photosynthesis and carbohydrate content of the seagrass Zostera noltii Hornem","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 3",NA,"2007","Lab","coastal",36.53,-6.25,"Cádiz, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",20,NA,"unknown","none","reduced light",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,165,NA,100,NA,4.141,"Growth rate (mg freshweight plant-1 day-1)","growth rate","biom","dSS",NA,7.88,NA,3.524,5,25,NA,15.2,NA,-0.11,"Growth rate (mg freshweight plant-1 day-1)",2,NA,1.773,NA,0.793,5,0.903,5.712,-0.672,0.423
"832",832,848,"380","Olive, I; Brun, FG; Vergara, JJ; Perez-Llorens, JL",2007,"Effects of light and Biomass partitioning on growth, photosynthesis and carbohydrate content of the seagrass Zostera noltii Hornem","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 7",NA,"2007","Lab","coastal",36.53,-6.25,"Cádiz, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",20,NA,"unknown","none","reduced light",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,165,NA,100,NA,31.663,"ETRm (µmol e m-2 s-1)","quantum yield","phys","dQ",NA,3.59,NA,1.607,5,25,NA,15.2,NA,26.864,"ETRm (µmol e m-2 s-1)",1,NA,4.577,NA,2.047,5,0.903,4.115,-1.054,0.455
"833",833,849,"380","Olive, I; Brun, FG; Vergara, JJ; Perez-Llorens, JL",2007,"Effects of light and Biomass partitioning on growth, photosynthesis and carbohydrate content of the seagrass Zostera noltii Hornem","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass",NA,"Fig 7",NA,"2007","Lab","coastal",36.53,-6.25,"Cádiz, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",20,NA,"unknown","none","reduced light",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,165,NA,100,NA,0.752,"Fv/Fm","quantum yield","phys","dQ",NA,0.01,NA,0.005,5,25,NA,15.2,NA,0.694,"Fv/Fm",1,NA,0.071,NA,0.032,5,0.903,0.051,-1.026,0.453
"834",834,850,"388","Warner, ME; Madden, ML",2007,"The impact of shifts to elevated irradiance on the growth and photochemical activity of the harmful algae Chattonella subsalsa and Prorocentrum minimum from Delaware","HARMFUL ALGAE",1,NA,NA,"Table 1",NA,"2007","Lab","coastal",38.69,-75.15,"Love Creek, Delaware, USA","Chatonella subsalsa","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","14",NA,NA,23,NA,NA,NA,36.3,882,36.3,882,NA,4,600,NA,100,NA,0.504,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.011,NA,0.006,3,30,NA,5,NA,0.263,"Growth rate (µ/d)",2,NA,0.006,NA,0.003,3,0.8,0.009,-21.761,40.127
"835",835,851,"388","Warner, ME; Madden, ML",2007,"The impact of shifts to elevated irradiance on the growth and photochemical activity of the harmful algae Chattonella subsalsa and Prorocentrum minimum from Delaware","HARMFUL ALGAE",1,NA,NA,"Table 1",NA,"2007","Lab","coastal",38.69,-75.15,"Love Creek, Delaware, USA","Prorocentrum minimum","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","14",NA,NA,23,NA,NA,NA,36.3,882,36.3,882,NA,4,600,NA,100,NA,0.694,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.023,NA,0.013,3,30,NA,5,NA,0.326,"Growth rate (µ/d)",2,NA,0.02,NA,0.012,3,0.8,0.022,-13.66,16.216
"836",836,852,"393","Sedwick, PN; Garcia, NS; Riseman, SF; Marsay, CM; DiTullio, GR",2007,"Evidence for high iron requirements of colonial Phaeocystis antarctica at low irradiance","BIOGEOCHEMISTRY",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2007","Field","offshore",-75.85,171.23,"Ross Sea, Antarctica","Total phytoplankton","phytoplankton",2.3,"in situ incubation","Polycarbonate bottles",1,NA,"yes","none","shading screen","natural",NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,4.722,"Chl a (µg/L)","biomass","biom","SS",NA,0.042,NA,0.03,2,NA,NA,30,NA,8.538,"Chl a (µg/L)",2,NA,0.084,NA,0.059,2,0.571,0.066,32.966,136.845
"837",837,853,"393","Sedwick, PN; Garcia, NS; Riseman, SF; Marsay, CM; DiTullio, GR",2007,"Evidence for high iron requirements of colonial Phaeocystis antarctica at low irradiance","BIOGEOCHEMISTRY",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2007","Field","offshore",-75.85,171.23,"Ross Sea, Antarctica","Total phytoplankton","phytoplankton",2.3,"in situ incubation","Polycarbonate bottles",1,NA,"yes","nutrients","shading screen","natural",NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,4.249,"Chl a (µg/L)","biomass","biom","SS",NA,0.46,NA,0.325,2,NA,NA,30,NA,6.024,"Chl a (µg/L)",2,NA,0.126,NA,0.089,2,0.571,0.337,3.007,2.13
"838",838,854,"393","Sedwick, PN; Garcia, NS; Riseman, SF; Marsay, CM; DiTullio, GR",2007,"Evidence for high iron requirements of colonial Phaeocystis antarctica at low irradiance","BIOGEOCHEMISTRY",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2007","Field","offshore",-75.85,171.23,"Ross Sea, Antarctica","Total phytoplankton","phytoplankton",2.3,"in situ incubation","Polycarbonate bottles",1,NA,"yes","nutrients","shading screen","natural",NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,5.55,"Chl a (µg/L)","biomass","biom","SS",NA,0.209,NA,0.148,2,NA,NA,30,NA,8.479,"Chl a (µg/L)",2,NA,0.502,NA,0.355,2,0.571,0.385,4.352,3.367
"839",839,855,"393","Sedwick, PN; Garcia, NS; Riseman, SF; Marsay, CM; DiTullio, GR",2007,"Evidence for high iron requirements of colonial Phaeocystis antarctica at low irradiance","BIOGEOCHEMISTRY",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2007","Field","offshore",-75.85,171.23,"Ross Sea, Antarctica","Total phytoplankton","phytoplankton",3.7,"in situ incubation","Polycarbonate bottles",1,NA,"yes","none","shading screen","natural",NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,5.668,"Chl a (µg/L)","biomass","biom","SS",NA,0.837,NA,0.592,2,NA,NA,30,NA,9.337,"Chl a (µg/L)",2,NA,0.251,NA,0.178,2,0.571,0.618,3.393,2.439
"840",840,856,"393","Sedwick, PN; Garcia, NS; Riseman, SF; Marsay, CM; DiTullio, GR",2007,"Evidence for high iron requirements of colonial Phaeocystis antarctica at low irradiance","BIOGEOCHEMISTRY",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2007","Field","offshore",-75.85,171.23,"Ross Sea, Antarctica","Total phytoplankton","phytoplankton",3.7,"in situ incubation","Polycarbonate bottles",1,NA,"yes","nutrients","shading screen","natural",NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,4.515,"Chl a (µg/L)","biomass","biom","SS",NA,0.042,NA,0.03,2,NA,NA,30,NA,8.923,"Chl a (µg/L)",2,NA,0.084,NA,0.059,2,0.571,0.066,38.077,182.233
"841",841,857,"393","Sedwick, PN; Garcia, NS; Riseman, SF; Marsay, CM; DiTullio, GR",2007,"Evidence for high iron requirements of colonial Phaeocystis antarctica at low irradiance","BIOGEOCHEMISTRY",1,"Light intensity means proportion of surface irridiance (not given)",NA,"Fig 2",NA,"2007","Field","offshore",-75.85,171.23,"Ross Sea, Antarctica","Total phytoplankton","phytoplankton",3.7,"in situ incubation","Polycarbonate bottles",1,NA,"yes","nutrients","shading screen","natural",NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,NA,8.006,"Chl a (µg/L)","biomass","biom","SS",NA,0.377,NA,0.266,2,NA,NA,30,NA,10.166,"Chl a (µg/L)",2,NA,0.586,NA,0.414,2,0.571,0.492,2.506,1.785
"842",842,858,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,150,NA,60,NA,0.419,"Growth rate (µ/d)",2,NA,0.031,NA,0.015,4,0.87,0.033,1.079,0.573
"843",843,859,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,100,NA,40,NA,0.391,"Growth rate (µ/d)",2,NA,0.031,NA,0.015,4,0.87,0.033,0.346,0.507
"844",844,860,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,80,NA,32,NA,0.448,"Growth rate (µ/d)",2,NA,0.022,NA,0.011,4,0.87,0.029,2.067,0.767
"845",845,861,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,50,NA,20,NA,0.407,"Growth rate (µ/d)",2,NA,0.009,NA,0.004,4,0.87,0.026,0.993,0.562
"846",846,862,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,35,NA,14,NA,0.314,"Growth rate (µ/d)",2,NA,0.026,NA,0.013,4,0.87,0.031,-1.776,0.697
"847",847,863,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,20,NA,8,NA,0.159,"Growth rate (µ/d)",2,NA,0.026,NA,0.013,4,0.87,0.031,-6.092,2.82
"848",848,864,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,10,NA,4,NA,0.115,"Growth rate (µ/d)",2,NA,0.031,NA,0.015,4,0.87,0.033,-6.896,3.472
"849",849,865,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.378,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,5,NA,2,NA,-0.026,"Growth rate (µ/d)",2,NA,0.013,NA,0.007,4,0.87,0.027,-13.19,11.374
"850",850,866,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,150,NA,60,NA,0.73,"Growth rate (µ/d)",2,NA,0.027,NA,0.013,4,0.87,0.031,-0.615,0.524
"851",851,867,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,100,NA,40,NA,0.73,"Growth rate (µ/d)",2,NA,0.018,NA,0.009,4,0.87,0.028,-0.687,0.53
"852",852,868,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,80,NA,32,NA,0.699,"Growth rate (µ/d)",2,NA,0.111,NA,0.055,4,0.87,0.082,-0.562,0.52
"853",853,869,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,50,NA,20,NA,0.601,"Growth rate (µ/d)",2,NA,0.031,NA,0.015,4,0.87,0.033,-3.933,1.467
"854",854,870,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,35,NA,14,NA,0.442,"Growth rate (µ/d)",2,NA,0.009,NA,0.004,4,0.87,0.026,-10.439,7.311
"855",855,871,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,20,NA,8,NA,0.3,"Growth rate (µ/d)",2,NA,0.093,NA,0.046,4,0.87,0.07,-5.582,2.447
"856",856,872,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,10,NA,4,NA,0.079,"Growth rate (µ/d)",2,NA,0.053,NA,0.027,4,0.87,0.045,-12.961,10.999
"857",857,873,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,0.752,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.035,NA,0.018,4,5,NA,2,NA,0.008,"Growth rate (µ/d)",2,NA,0.022,NA,0.011,4,0.87,0.03,-21.899,30.474
"858",858,874,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,150,NA,60,NA,17.677,"photosynthetic activity (pg C/cell h)",1,NA,2.279,NA,1.316,3,0.8,2.757,0.612,0.698
"859",859,875,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,100,NA,40,NA,17.656,"photosynthetic activity (pg C/cell h)",1,NA,2.532,NA,1.462,3,0.8,2.866,0.583,0.695
"860",860,876,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,80,NA,32,NA,20.559,"photosynthetic activity (pg C/cell h)",1,NA,5.317,NA,3.07,3,0.8,4.375,0.913,0.736
"861",861,877,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,50,NA,20,NA,24.344,"photosynthetic activity (pg C/cell h)",1,NA,3.291,NA,1.9,3,0.8,3.228,2.175,1.061
"862",862,878,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,35,NA,14,NA,17.629,"photosynthetic activity (pg C/cell h)",1,NA,3.924,NA,2.266,3,0.8,3.564,0.463,0.684
"863",863,879,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,20,NA,8,NA,8.382,"photosynthetic activity (pg C/cell h)",1,NA,2.152,NA,1.242,3,0.8,2.706,-2.125,1.043
"864",864,880,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,10,NA,4,NA,3.441,"photosynthetic activity (pg C/cell h)",1,NA,2.405,NA,1.389,3,0.8,2.81,-3.452,1.66
"865",865,881,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Heterocapsa triquetra","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,15.568,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.164,NA,1.827,3,5,NA,2,NA,0.78,"photosynthetic activity (pg C/cell h)",1,NA,0.506,NA,0.292,3,0.8,2.266,-5.221,2.938
"866",866,882,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,150,NA,60,NA,17.501,"photosynthetic activity (pg C/cell h)",1,NA,2.797,NA,1.615,3,0.8,2.993,0.311,0.675
"867",867,883,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,100,NA,40,NA,18.147,"photosynthetic activity (pg C/cell h)",1,NA,1.653,NA,0.954,3,0.8,2.533,0.572,0.694
"868",868,884,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,80,NA,32,NA,13.194,"photosynthetic activity (pg C/cell h)",1,NA,3.941,NA,2.275,3,0.8,3.58,-0.702,0.708
"869",869,885,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,50,NA,20,NA,12.183,"photosynthetic activity (pg C/cell h)",1,NA,1.525,NA,0.881,3,0.8,2.493,-1.333,0.815
"870",870,886,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,35,NA,14,NA,7.864,"photosynthetic activity (pg C/cell h)",1,NA,0.89,NA,0.514,3,0.8,2.334,-2.904,1.37
"871",871,887,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,20,NA,8,NA,5.834,"photosynthetic activity (pg C/cell h)",1,NA,0.636,NA,0.367,3,0.8,2.292,-3.666,1.787
"872",872,888,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,10,NA,4,NA,3.039,"photosynthetic activity (pg C/cell h)",1,NA,0.508,NA,0.294,3,0.8,2.276,-4.674,2.487
"873",873,889,"405","Nielsen, LT; Lundholm, N; Hansen, PJ",2007,"Does irradiance influence the tolerance of marine phytoplankton to high pH?","MARINE BIOLOGY RESEARCH",1,"Temperature was derived from another experiment of the study, for the growth experiment no temperature was given",NA,"Fig 1",NA,"2007","Lab","culture",NA,NA,NA,"Nitschia navis varingica","phytoplankton",5,"microcosm","flasks",NA,NA,"no","none","reduced light","16",NA,NA,16.5,NA,NA,30,36.3,882,36.3,882,NA,4,250,NA,100,NA,16.336,"photosynthetic activity (pg C/cell h)","mass-specific production","phys","dQ",NA,3.178,NA,1.835,3,5,NA,2,NA,0.498,"photosynthetic activity (pg C/cell h)",1,NA,0.381,NA,0.22,3,0.8,2.263,-5.598,3.278
"874",874,890,"416","Ilyash, LV; Zapara, EV",2006,"Competition of two marine diatom algae for urea and nitrate nitrogen under three levels of irradiance","ZHURNAL OBSHCHEI BIOLOGII",1,NA,"Article is in Russian language",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"875",875,891,"422","Floder, S; Hansen, T; Ptacnik, R",2006,"Energy-dependent bacterivory in Ochromonas minima - A strategy promoting the use of substitutable resources and survival at insufficient light supply","PROTIST",1,"mixotrophs",NA,"Fig 4 C",NA,"2006","Lab","culture",NA,NA,NA,"Ochromonas minima","phytoplankton",12,"microcosm","Erlenmeyer flask",0.15,NA,"no","none","reduced light",NA,NA,NA,16,NA,NA,25,NA,NA,0.11,7,NA,2,60,NA,100,NA,0.391,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.02,NA,0.012,3,1,NA,1.7,NA,0.006,"Growth rate (µ/d)",2,NA,0.017,NA,0.01,3,0.8,0.019,-16.541,23.468
"876",876,892,"429","Lafarga-De la Cruz, F; Valenzuela-Espinoza, E; Millan-Nunez, R; Trees, CC; Santamaria-del-Angel, E; Nunez-Cebrero, F",2006,"Nutrient uptake, chlorophyll a and carbon fixation by Rhodomonas sp (Cryptophyceae) cultured at different irradiance and nutrient concentrations","AQUACULTURAL ENGINEERING",1,"extremely high nutrients","data points are not readily visible in figure 1",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"877",877,893,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,2.453,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.86,NA,0.387,5,106,NA,50,NA,1.196,"Sediment PP (mg C m-2 h-1)",1,NA,0.27,NA,0.121,5,0.903,0.641,-1.772,0.557
"878",878,894,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,0.77,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.09,NA,0.039,5,43,NA,50,NA,0.596,"Sediment PP (mg C m-2 h-1)",1,NA,0.087,NA,0.039,5,0.903,0.087,-1.805,0.563
"879",879,895,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,46.296,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,8.97,NA,4.012,5,106,NA,50,NA,15.432,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,5.521,NA,2.469,5,0.903,7.449,-3.742,1.1
"880",880,896,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,2.535,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,2.26,NA,1.01,5,43,NA,50,NA,2.219,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,2.634,NA,1.178,5,0.903,2.453,-0.116,0.401
"881",881,897,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,26.963,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,7.95,NA,3.556,5,106,NA,50,NA,-2.963,"Sediment NET PP (mg C m-2 h-1)",1,NA,4.638,NA,2.074,5,0.903,6.508,-4.153,1.262
"882",882,898,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,-10.933,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,2.09,NA,0.933,5,43,NA,50,NA,-11.467,"Sediment NET PP (mg C m-2 h-1)",1,NA,1.789,NA,0.8,5,0.903,1.944,-0.248,0.403
"883",883,899,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,0.02,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.06,NA,0.026,5,14,NA,50,NA,0.04,"Sediment PP (mg C m-2 h-1)",1,NA,0.012,NA,0.005,5,0.903,0.041,0.445,0.41
"884",884,900,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,3.505,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,12.91,NA,5.773,5,63,NA,50,NA,3.505,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,13.37,NA,5.979,5,0.903,13.142,0,0.4
"885",885,901,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,4.896,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,21.43,NA,9.583,5,14,NA,50,NA,8.646,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,3.727,NA,1.667,5,0.903,15.38,0.22,0.402
"886",886,902,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,-26.267,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,17.95,NA,8.026,5,63,NA,50,NA,-31.907,"Sediment NET PP (mg C m-2 h-1)",1,NA,15.705,NA,7.023,5,0.903,16.862,-0.302,0.405
"887",887,903,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",2,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,-36.267,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,17.29,NA,7.733,5,14,NA,50,NA,-35.467,"Sediment NET PP (mg C m-2 h-1)",1,NA,4.77,NA,2.133,5,0.903,12.684,0.057,0.4
"888",888,904,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","winter","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,17,NA,NA,9.8,0.1,22.33,0.1,22.33,NA,4,538,NA,100,NA,6.801,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.93,NA,0.415,5,269,NA,50,NA,3.85,"Sediment PP (mg C m-2 h-1)",1,NA,1.134,NA,0.507,5,0.903,1.036,-2.572,0.731
"889",889,905,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,3.178,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,1.22,NA,0.544,5,106,NA,50,NA,1.752,"Sediment PP (mg C m-2 h-1)",1,NA,0.162,NA,0.073,5,0.903,0.867,-1.485,0.51
"890",890,906,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,0.934,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.16,NA,0.073,5,43,NA,50,NA,0.759,"Sediment PP (mg C m-2 h-1)",1,NA,0.075,NA,0.034,5,0.903,0.127,-1.247,0.478
"891",891,907,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","fall","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.6,NA,NA,8.7,0.3,4.5,0.3,4.5,NA,4,208,NA,100,NA,54.265,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,18.74,NA,8.382,5,104,NA,50,NA,23.824,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,8.879,NA,3.971,5,0.903,14.665,-1.875,0.576
"892",892,908,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,39.506,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,17.94,NA,8.025,5,106,NA,50,NA,25.926,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,16.563,NA,7.407,5,0.903,17.267,-0.71,0.425
"893",893,909,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,6.793,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,4.14,NA,1.852,5,43,NA,50,NA,7.993,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,5.648,NA,2.526,5,0.903,4.953,0.219,0.402
"894",894,910,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","fall","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.6,NA,NA,8.7,0.3,4.5,0.3,4.5,NA,4,208,NA,100,NA,36.047,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,18.72,NA,8.372,5,104,NA,50,NA,4.95,"Sediment NET PP (mg C m-2 h-1)",1,NA,3.566,NA,1.595,5,0.903,13.475,-2.084,0.617
"895",895,911,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,15.704,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,17.23,NA,7.704,5,106,NA,50,NA,10.963,"Sediment NET PP (mg C m-2 h-1)",1,NA,14.576,NA,6.519,5,0.903,15.956,-0.268,0.404
"896",896,912,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,-14.533,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,2.98,NA,1.333,5,43,NA,50,NA,-13.6,"Sediment NET PP (mg C m-2 h-1)",1,NA,5.665,NA,2.533,5,0.903,4.526,0.186,0.402
"897",897,913,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","winter","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,12.7,NA,NA,8.6,0.06,27.6,0.06,27.6,NA,4,590,NA,100,NA,1.159,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.84,NA,0.377,5,295,NA,50,NA,1.213,"Sediment PP (mg C m-2 h-1)",1,NA,0.562,NA,0.251,5,0.903,0.717,0.068,0.4
"898",898,914,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,0.973,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.72,NA,0.321,5,63,NA,50,NA,0.625,"Sediment PP (mg C m-2 h-1)",1,NA,0.18,NA,0.08,5,0.903,0.524,-0.6,0.418
"899",899,915,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,0.064,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.03,NA,0.012,5,14,NA,50,NA,0.055,"Sediment PP (mg C m-2 h-1)",1,NA,0.018,NA,0.008,5,0.903,0.022,-0.37,0.407
"900",900,916,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","fall","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,21.6,NA,NA,10.1,0.1,15.2,0.1,15.2,NA,4,537,NA,100,NA,121.804,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,29.53,NA,13.205,5,269,NA,50,NA,118.377,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,23.626,NA,10.566,5,0.903,26.74,-0.116,0.401
"901",901,917,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","winter","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,12.7,NA,NA,8.6,0.06,27.6,0.06,27.6,NA,4,590,NA,100,NA,14.302,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,2.5,NA,1.119,5,295,NA,50,NA,6.715,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,3.753,NA,1.678,5,0.903,3.189,-2.149,0.631
"902",902,918,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,19.175,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,11.07,NA,4.948,5,63,NA,50,NA,16.289,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,20.978,NA,9.381,5,0.903,16.77,-0.155,0.401
"903",903,919,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,4.583,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,7.92,NA,3.542,5,14,NA,50,NA,2.812,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,9.317,NA,4.167,5,0.903,8.646,-0.185,0.402
"904",904,920,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","fall","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,21.6,NA,NA,10.1,0.1,15.2,0.1,15.2,NA,4,537,NA,100,NA,100,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,26.43,NA,11.818,5,269,NA,50,NA,87.273,"Sediment NET PP (mg C m-2 h-1)",1,NA,16.262,NA,7.273,5,0.903,21.941,-0.524,0.414
"905",905,921,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","winter","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,12.7,NA,NA,8.6,0.06,27.6,0.06,27.6,NA,4,590,NA,100,NA,5.304,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,2.79,NA,1.25,5,295,NA,50,NA,-3.624,"Sediment NET PP (mg C m-2 h-1)",1,NA,2.486,NA,1.112,5,0.903,2.644,-3.05,0.865
"906",906,922,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,-1.407,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,5.23,NA,2.341,5,63,NA,50,NA,-15.074,"Sediment NET PP (mg C m-2 h-1)",1,NA,8.974,NA,4.013,5,0.903,7.346,-1.68,0.541
"907",907,923,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",4,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,-30.667,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,10.14,NA,4.533,5,14,NA,50,NA,-29.067,"Sediment NET PP (mg C m-2 h-1)",1,NA,7.155,NA,3.2,5,0.903,8.774,0.165,0.401
"908",908,924,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","winter","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,17,NA,NA,9.8,0.1,22.33,0.1,22.33,NA,4,538,NA,100,NA,1.914,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.72,NA,0.323,5,269,NA,50,NA,1.176,"Sediment PP (mg C m-2 h-1)",1,NA,1.547,NA,0.692,5,0.903,1.207,-0.552,0.415
"909",909,925,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,3.275,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,1.08,NA,0.483,5,106,NA,50,NA,1.873,"Sediment PP (mg C m-2 h-1)",1,NA,0.594,NA,0.266,5,0.903,0.872,-1.452,0.505
"910",910,926,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,1.545,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.29,NA,0.129,5,43,NA,50,NA,0.806,"Sediment PP (mg C m-2 h-1)",1,NA,0.312,NA,0.14,5,0.903,0.3,-2.224,0.647
"911",911,927,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","fall","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.6,NA,NA,8.7,0.3,4.5,0.3,4.5,NA,4,208,NA,100,NA,44.118,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,11.84,NA,5.294,5,104,NA,50,NA,16.324,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,11.838,NA,5.294,5,0.903,11.838,-2.121,0.625
"912",912,928,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,95.062,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,11.04,NA,4.938,5,106,NA,50,NA,36.42,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,16.563,NA,7.407,5,0.903,14.076,-3.763,1.108
"913",913,929,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,14.252,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,9.03,NA,4.04,5,43,NA,50,NA,11.577,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,13.178,NA,5.893,5,0.903,11.298,-0.214,0.402
"914",914,930,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","fall","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.6,NA,NA,8.7,0.3,4.5,0.3,4.5,NA,4,208,NA,100,NA,43.621,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,8.91,NA,3.987,5,104,NA,50,NA,6.146,"Sediment NET PP (mg C m-2 h-1)",1,NA,11.589,NA,5.183,5,0.903,10.339,-3.274,0.936
"915",915,931,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","spring","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,28.3,NA,NA,2.7,0.16,13.4,0.16,13.4,NA,4,212,NA,100,NA,70.815,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,15.9,NA,7.111,5,106,NA,50,NA,21.63,"Sediment NET PP (mg C m-2 h-1)",1,NA,17.889,NA,8,5,0.903,16.924,-2.625,0.745
"916",916,932,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","summer","2006","Field","coastal",30.39,-87.82,"Magnolia River, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,29.4,NA,NA,0.2,0.8,11.7,0.8,11.7,NA,4,86,NA,100,NA,-10.4,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,10.73,NA,4.8,5,43,NA,50,NA,-11.467,"Sediment NET PP (mg C m-2 h-1)",1,NA,16.1,NA,7.2,5,0.903,13.682,-0.07,0.4
"917",917,933,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","winter","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,12.7,NA,NA,8.6,0.06,27.6,0.06,27.6,NA,4,590,NA,100,NA,2.039,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.92,NA,0.413,5,295,NA,50,NA,1.105,"Sediment PP (mg C m-2 h-1)",1,NA,0.844,NA,0.377,5,0.903,0.885,-0.954,0.445
"918",918,934,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,1.741,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,2.52,NA,1.125,5,63,NA,50,NA,0.446,"Sediment PP (mg C m-2 h-1)",1,NA,0.539,NA,0.241,5,0.903,1.819,-0.643,0.421
"919",919,935,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 3","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,0.01,"Sediment PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,0.01,NA,0.006,5,14,NA,50,NA,0.043,"Sediment PP (mg C m-2 h-1)",1,NA,0.022,NA,0.01,5,0.903,0.018,1.633,0.533
"920",920,936,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","fall","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,21.6,NA,NA,10.1,0.1,15.2,0.1,15.2,NA,4,537,NA,100,NA,65.697,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,13.78,NA,6.163,5,269,NA,50,NA,34.098,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,27.57,NA,12.33,5,0.903,21.795,-1.309,0.486
"921",921,937,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","winter","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,12.7,NA,NA,8.6,0.06,27.6,0.06,27.6,NA,4,590,NA,100,NA,24.565,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,23.14,NA,10.35,5,295,NA,50,NA,25.368,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,5.629,NA,2.517,5,0.903,16.841,0.043,0.4
"922",922,938,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,13.608,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,5.53,NA,2.474,5,63,NA,50,NA,5.979,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,11.987,NA,5.361,5,0.903,9.335,-0.738,0.427
"923",923,939,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 4","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,2.292,"Sediment GROSS PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,8.85,NA,3.958,5,14,NA,50,NA,1.302,"Sediment GROSS PP (mg C m-2 h-1)",1,NA,5.94,NA,2.656,5,0.903,7.537,-0.119,0.401
"924",924,940,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","fall","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,21.6,NA,NA,10.1,0.1,15.2,0.1,15.2,NA,4,537,NA,100,NA,41.818,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,14.23,NA,6.364,5,269,NA,50,NA,-11.818,"Sediment NET PP (mg C m-2 h-1)",1,NA,8.131,NA,3.636,5,0.903,11.589,-4.18,1.274
"925",925,941,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","winter","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,12.7,NA,NA,8.6,0.06,27.6,0.06,27.6,NA,4,590,NA,100,NA,-14.931,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,17.08,NA,7.639,5,295,NA,50,NA,-16.357,"Sediment NET PP (mg C m-2 h-1)",1,NA,9.938,NA,4.444,5,0.903,13.974,-0.092,0.4
"926",926,942,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","spring","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,24.7,NA,NA,1.2,0.08,6.2,0.08,6.2,NA,4,127,NA,100,NA,-0.126,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,3.74,NA,1.672,5,63,NA,50,NA,-14.797,"Sediment NET PP (mg C m-2 h-1)",1,NA,7.854,NA,3.512,5,0.903,6.15,-2.155,0.632
"927",927,943,"439","Stutes, AL; Cebrian, J; Corcoran, AA",2006,"Effects of nutrient enrichment and shading on sediment primary production and metabolism in eutrophic estuaries","MARINE ECOLOGY PROGRESS SERIES",1,"Not sure what kind of primary production is shown in figure 3; Nutrient values are those measured in the water column",NA,"Fig 6","summer","2006","Field","coastal",30.41,-87.83,"Weeks Bay, USA","Total Phytobenthos","phytobenthos",6,"field plot","no container",NA,1,"yes","none","shading screen","natural",NA,NA,27.8,NA,NA,0.2,0.1,2.7,0.1,2.7,NA,4,28,NA,100,NA,-17.867,"Sediment NET PP (mg C m-2 h-1)","area-specific production","biom","dSS",NA,1.79,NA,0.8,5,14,NA,50,NA,-16.8,"Sediment NET PP (mg C m-2 h-1)",1,NA,4.174,NA,1.867,5,0.903,3.211,0.3,0.405
"928",928,944,"440","Carter, CM; Ross, AH; Schiel, DR; Howard-Williams, C; Hayden, B",2005,"In situ microcosm experiments on the influence of nitrate and light on phytoplankton community composition","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,NA,"Relevant plots could not be evaluated",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"929",929,945,"449","Fokeera-Wahedally, SBM; Bhikajee, M",2005,"The effects of in situ shading on the growth of a seagrass, Syringodium isoetifolium","ESTUARINE COASTAL AND SHELF SCIENCE",1,"seagrass","The degree of shading is not given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"930",930,946,"460","Patel, D; Thake, B; Thornton, DCO",2005,"Effect of light and turbulent mixing on the growth of Skeletonema costatum (Bacillariophyceae)","MARINE BIOLOGY",1,NA,"Light changes were made by varying mixing depth and time, no real relationship between light intensity and growth",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"931",931,947,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain MI)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.684,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.062,NA,0.044,2,175,NA,41.2,NA,0.354,"Growth rate (µ/d)",2,NA,0.072,NA,0.051,2,0.571,0.067,-2.808,1.986
"932",932,948,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain MI)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.684,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.062,NA,0.044,2,100,NA,23.5,NA,0.299,"Growth rate (µ/d)",2,NA,0.002,NA,0.001,2,0.571,0.044,-4.998,4.122
"933",933,949,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain MI)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.684,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.062,NA,0.044,2,50,NA,11.8,NA,0.138,"Growth rate (µ/d)",2,NA,0.089,NA,0.063,2,0.571,0.077,-4.052,3.053
"934",934,950,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain MI)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.684,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.062,NA,0.044,2,25,NA,5.9,NA,0.107,"Growth rate (µ/d)",2,NA,0.054,NA,0.039,2,0.571,0.058,-5.645,4.983
"935",935,951,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain MI)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.684,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.062,NA,0.044,2,6,NA,1.4,NA,-0.049,"Growth rate (µ/d)",2,NA,0.062,NA,0.044,2,0.571,0.062,-6.732,6.665
"936",936,952,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain BoF)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.505,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.06,NA,0.043,2,175,NA,41.2,NA,0.315,"Growth rate (µ/d)",2,NA,0.018,NA,0.012,2,0.571,0.044,-2.453,1.752
"937",937,953,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain BoF)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.505,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.06,NA,0.043,2,100,NA,23.5,NA,0.156,"Growth rate (µ/d)",2,NA,0.007,NA,0.005,2,0.571,0.043,-4.65,3.703
"938",938,954,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain BoF)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.505,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.06,NA,0.043,2,50,NA,11.8,NA,0.165,"Growth rate (µ/d)",2,NA,0.029,NA,0.021,2,0.571,0.047,-4.107,3.108
"939",939,955,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain BoF)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.505,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.06,NA,0.043,2,25,NA,5.9,NA,0.128,"Growth rate (µ/d)",2,NA,0.043,NA,0.03,2,0.571,0.052,-4.124,3.126
"940",940,956,"464","Etheridge, SM; Roesler, CS",2005,"Effects of temperature, irradiance, and salinity on photosynthesis, growth rates, total toxicity, and toxin composition for Alexandrium fundyense isolates from the Gulf of Maine and Bay of Fundy","DEEP-SEA RESEARCH PART II-TOPICAL STUDIES IN OCEANOGRAPHY",1,"Number of replicates are not given, it is only spoken of 'replicate measurements'. Thus I assumed n=2",NA,"Fig 2B",NA,"2005","Lab","culture",NA,NA,NA,"Alexandrium fundyense (Strain BoF)","phytoplankton",NA,"microcosm","flasks",3,NA,"no","none","reduced light","14",NA,NA,20,NA,NA,30,36.3,882,36.3,882,107,5,425,NA,100,NA,0.505,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.06,NA,0.043,2,6,NA,1.4,NA,-0.098,"Growth rate (µ/d)",2,NA,0.053,NA,0.037,2,0.571,0.057,-6.094,5.642
"941",941,957,"465","Timmermans, KR; van der Wagt, B; Veldhuis, MJW; Maatman, A; de Baar, HJW",2005,"Physiological responses of three species of marine pico-phytoplankton to ammonium, phosphate, iron and light limitation","JOURNAL OF SEA RESEARCH",1,NA,"No replicates of the experiments",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"942",942,958,"466","Malta, EJ; Ferreira, DG; Vergara, JJ; Perez-Llorens, JL",2005,"Nitrogen load and irradiance affect morphology, photosynthesis and growth of Caulerpa prolifera (Bryopsidales : Chlorophyta)","MARINE ECOLOGY PROGRESS SERIES",1,"macroalgae","number of replicates not clear",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"943",943,961,"480","Needoba, JA; Harrison, PJ",2004,"Influence of low light and a light: Dark cycle on NO3- uptake, intracellular NO3-, and nitrogen isotope fractionation by marine phytoplankton","JOURNAL OF PHYCOLOGY",1,NA,NA,"Table 1",NA,"2004","Lab","culture",NA,NA,NA,"Thalssiosira rotula","phytoplankton",4,"microcosm","Borosilicate flask",2.5,NA,"no","none","reduced light","24",NA,NA,18,NA,NA,NA,100,200,100,200,500,5,140,NA,100,NA,0.57,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.01,NA,0.006,3,14,NA,10,NA,0.31,"Growth rate (µ/d)",2,NA,0.02,NA,0.012,3,0.8,0.016,-13.155,15.088
"944",944,959,"480","Needoba, JA; Harrison, PJ",2004,"Influence of low light and a light: Dark cycle on NO3- uptake, intracellular NO3-, and nitrogen isotope fractionation by marine phytoplankton","JOURNAL OF PHYCOLOGY",1,NA,NA,"Table 1",NA,"2004","Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",5,"microcosm","Borosilicate flask",2.5,NA,"no","none","reduced light","24",NA,NA,18,NA,NA,NA,100,200,100,200,500,5,140,NA,100,NA,1.8,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.01,NA,0.006,3,14,NA,10,NA,0.29,"Growth rate (µ/d)",2,NA,0.03,NA,0.017,3,0.8,0.022,-54.023,243.877
"945",945,962,"480","Needoba, JA; Harrison, PJ",2004,"Influence of low light and a light: Dark cycle on NO3- uptake, intracellular NO3-, and nitrogen isotope fractionation by marine phytoplankton","JOURNAL OF PHYCOLOGY",1,NA,NA,"Table 1",NA,"2004","Lab","culture",NA,NA,NA,"Emiliana huxleyi","phytoplankton",7,"microcosm","Borosilicate flask",2.5,NA,"no","none","reduced light","24",NA,NA,18,NA,NA,NA,100,200,100,200,500,5,140,NA,100,NA,0.74,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.31,NA,0.179,3,14,NA,10,NA,0.22,"Growth rate (µ/d)",2,NA,0.03,NA,0.017,3,0.8,0.22,-1.889,0.964
"946",946,960,"480","Needoba, JA; Harrison, PJ",2004,"Influence of low light and a light: Dark cycle on NO3- uptake, intracellular NO3-, and nitrogen isotope fractionation by marine phytoplankton","JOURNAL OF PHYCOLOGY",1,NA,NA,"Table 1",NA,"2004","Lab","culture",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",8,"microcosm","Borosilicate flask",2.5,NA,"no","none","reduced light","24",NA,NA,18,NA,NA,NA,100,200,100,200,500,5,140,NA,100,NA,0.89,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.14,NA,0.081,3,14,NA,10,NA,0.19,"Growth rate (µ/d)",2,NA,0.04,NA,0.023,3,0.8,0.103,-5.439,3.132
"947",947,963,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",1,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.891,"Chl a (µg/L)","biomass","biom","SS",NA,0.806,NA,0.465,3,65,NA,46.4,NA,0.837,"Chl a (µg/L)",2,NA,0.515,NA,0.297,3,0.8,0.676,-0.064,0.667
"948",948,972,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",1,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.933,"Chl a (µg/L)","biomass","biom","SS",NA,0.741,NA,0.428,3,65,NA,46.4,NA,0.927,"Chl a (µg/L)",2,NA,0.746,NA,0.431,3,0.8,0.744,-0.006,0.667
"949",949,981,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",1,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.891,"Chl a (µg/L)","biomass","biom","SS",NA,0.806,NA,0.465,3,19,NA,13.6,NA,0.701,"Chl a (µg/L)",2,NA,0.363,NA,0.21,3,0.8,0.625,-0.244,0.672
"950",950,990,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",1,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.933,"Chl a (µg/L)","biomass","biom","SS",NA,0.741,NA,0.428,3,19,NA,13.6,NA,0.605,"Chl a (µg/L)",2,NA,0.343,NA,0.198,3,0.8,0.578,-0.455,0.684
"951",951,964,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",2,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,1.515,"Chl a (µg/L)","biomass","biom","SS",NA,1.045,NA,0.603,3,65,NA,46.4,NA,1.279,"Chl a (µg/L)",2,NA,0.839,NA,0.485,3,0.8,0.948,-0.199,0.67
"952",952,973,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",2,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,1.463,"Chl a (µg/L)","biomass","biom","SS",NA,1.053,NA,0.608,3,65,NA,46.4,NA,1.426,"Chl a (µg/L)",2,NA,1.084,NA,0.626,3,0.8,1.069,-0.028,0.667
"953",953,982,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",2,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,1.515,"Chl a (µg/L)","biomass","biom","SS",NA,1.045,NA,0.603,3,19,NA,13.6,NA,0.669,"Chl a (µg/L)",2,NA,0.404,NA,0.233,3,0.8,0.792,-0.854,0.727
"954",954,991,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",2,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,1.463,"Chl a (µg/L)","biomass","biom","SS",NA,1.053,NA,0.608,3,19,NA,13.6,NA,0.654,"Chl a (µg/L)",2,NA,0.355,NA,0.205,3,0.8,0.786,-0.823,0.723
"955",955,965,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",3,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,1.964,"Chl a (µg/L)","biomass","biom","SS",NA,1.52,NA,0.877,3,65,NA,46.4,NA,1.588,"Chl a (µg/L)",2,NA,1.087,NA,0.628,3,0.8,1.321,-0.227,0.671
"956",956,974,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",3,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,2.008,"Chl a (µg/L)","biomass","biom","SS",NA,1.485,NA,0.857,3,65,NA,46.4,NA,1.878,"Chl a (µg/L)",2,NA,1.593,NA,0.92,3,0.8,1.54,-0.067,0.667
"957",957,983,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",3,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,1.964,"Chl a (µg/L)","biomass","biom","SS",NA,1.52,NA,0.877,3,19,NA,13.6,NA,0.567,"Chl a (µg/L)",2,NA,0.354,NA,0.204,3,0.8,1.103,-1.013,0.752
"958",958,992,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",3,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,2.008,"Chl a (µg/L)","biomass","biom","SS",NA,1.485,NA,0.857,3,19,NA,13.6,NA,0.574,"Chl a (µg/L)",2,NA,0.247,NA,0.142,3,0.8,1.064,-1.078,0.763
"959",959,966,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",4,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,2.594,"Chl a (µg/L)","biomass","biom","SS",NA,1.601,NA,0.924,3,65,NA,46.4,NA,1.678,"Chl a (µg/L)",2,NA,0.711,NA,0.411,3,0.8,1.239,-0.591,0.696
"960",960,975,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",4,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,2.754,"Chl a (µg/L)","biomass","biom","SS",NA,1.755,NA,1.013,3,65,NA,46.4,NA,2.566,"Chl a (µg/L)",2,NA,1.914,NA,1.105,3,0.8,1.836,-0.082,0.667
"961",961,984,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",4,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,2.594,"Chl a (µg/L)","biomass","biom","SS",NA,1.601,NA,0.924,3,19,NA,13.6,NA,0.605,"Chl a (µg/L)",2,NA,0.366,NA,0.211,3,0.8,1.161,-1.37,0.823
"962",962,993,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",4,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,2.754,"Chl a (µg/L)","biomass","biom","SS",NA,1.755,NA,1.013,3,19,NA,13.6,NA,0.514,"Chl a (µg/L)",2,NA,0.294,NA,0.17,3,0.8,1.259,-1.424,0.836
"963",963,967,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",5,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,4.181,"Chl a (µg/L)","biomass","biom","SS",NA,3.828,NA,2.21,3,65,NA,46.4,NA,3.168,"Chl a (µg/L)",2,NA,3.141,NA,1.814,3,0.8,3.502,-0.231,0.671
"964",964,976,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",5,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,5.284,"Chl a (µg/L)","biomass","biom","SS",NA,4.261,NA,2.46,3,65,NA,46.4,NA,4.809,"Chl a (µg/L)",2,NA,4.681,NA,2.703,3,0.8,4.476,-0.085,0.667
"965",965,985,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",5,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,4.181,"Chl a (µg/L)","biomass","biom","SS",NA,3.828,NA,2.21,3,19,NA,13.6,NA,0.637,"Chl a (µg/L)",2,NA,0.548,NA,0.316,3,0.8,2.735,-1.037,0.756
"966",966,994,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",5,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,5.284,"Chl a (µg/L)","biomass","biom","SS",NA,4.261,NA,2.46,3,19,NA,13.6,NA,0.785,"Chl a (µg/L)",2,NA,0.725,NA,0.419,3,0.8,3.056,-1.178,0.782
"967",967,968,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",6,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,5.494,"Chl a (µg/L)","biomass","biom","SS",NA,4.095,NA,2.364,3,65,NA,46.4,NA,3.73,"Chl a (µg/L)",2,NA,3.329,NA,1.922,3,0.8,3.732,-0.378,0.679
"968",968,977,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",6,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,6.882,"Chl a (µg/L)","biomass","biom","SS",NA,3.126,NA,1.805,3,65,NA,46.4,NA,5.29,"Chl a (µg/L)",2,NA,4.336,NA,2.504,3,0.8,3.78,-0.337,0.676
"969",969,986,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",6,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,5.494,"Chl a (µg/L)","biomass","biom","SS",NA,4.095,NA,2.364,3,19,NA,13.6,NA,0.657,"Chl a (µg/L)",2,NA,0.573,NA,0.331,3,0.8,2.924,-1.324,0.813
"970",970,995,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",6,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,6.882,"Chl a (µg/L)","biomass","biom","SS",NA,3.126,NA,1.805,3,19,NA,13.6,NA,0.871,"Chl a (µg/L)",2,NA,0.752,NA,0.434,3,0.8,2.273,-2.115,1.04
"971",971,969,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",7,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,6.373,"Chl a (µg/L)","biomass","biom","SS",NA,4.229,NA,2.442,3,65,NA,46.4,NA,4.399,"Chl a (µg/L)",2,NA,3.771,NA,2.177,3,0.8,4.007,-0.394,0.68
"972",972,978,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",7,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,8.495,"Chl a (µg/L)","biomass","biom","SS",NA,2.195,NA,1.267,3,65,NA,46.4,NA,6.295,"Chl a (µg/L)",2,NA,3.779,NA,2.182,3,0.8,3.09,-0.569,0.694
"973",973,987,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",7,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,6.373,"Chl a (µg/L)","biomass","biom","SS",NA,4.229,NA,2.442,3,19,NA,13.6,NA,0.639,"Chl a (µg/L)",2,NA,0.513,NA,0.296,3,0.8,3.012,-1.523,0.86
"974",974,996,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",7,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,8.495,"Chl a (µg/L)","biomass","biom","SS",NA,2.195,NA,1.267,3,19,NA,13.6,NA,0.863,"Chl a (µg/L)",2,NA,0.727,NA,0.42,3,0.8,1.635,-3.734,1.829
"975",975,970,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",8,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,5.145,"Chl a (µg/L)","biomass","biom","SS",NA,2.521,NA,1.782,2,65,NA,46.4,NA,2.587,"Chl a (µg/L)",2,NA,0.753,NA,0.533,2,0.571,1.86,-0.786,1.077
"976",976,979,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",8,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,9.295,"Chl a (µg/L)","biomass","biom","SS",NA,0.2,NA,0.141,2,65,NA,46.4,NA,6.463,"Chl a (µg/L)",2,NA,2.272,NA,1.606,2,0.571,1.612,-1.004,1.126
"977",977,988,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",8,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,5.145,"Chl a (µg/L)","biomass","biom","SS",NA,2.521,NA,1.782,2,19,NA,13.6,NA,0.274,"Chl a (µg/L)",2,NA,0.182,NA,0.129,2,0.571,1.787,-1.557,1.303
"978",978,997,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",8,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,9.295,"Chl a (µg/L)","biomass","biom","SS",NA,0.2,NA,0.141,2,19,NA,13.6,NA,0.461,"Chl a (µg/L)",2,NA,0.212,NA,0.15,2,0.571,0.206,-24.503,76.048
"979",979,971,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",9,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,7.292,"Chl a (µg/L)","biomass","biom","SS",NA,3.121,NA,2.207,2,65,NA,46.4,NA,3.252,"Chl a (µg/L)",2,NA,0.783,NA,0.554,2,0.571,2.275,-1.015,1.129
"980",980,980,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",9,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,10.549,"Chl a (µg/L)","biomass","biom","SS",NA,2.342,NA,1.656,2,65,NA,46.4,NA,8.884,"Chl a (µg/L)",2,NA,3.024,NA,2.138,2,0.571,2.704,-0.352,1.015
"981",981,989,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",9,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,7.292,"Chl a (µg/L)","biomass","biom","SS",NA,3.121,NA,2.207,2,19,NA,13.6,NA,0.243,"Chl a (µg/L)",2,NA,0.168,NA,0.119,2,0.571,2.21,-1.823,1.415
"982",982,998,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 2","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",9,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,10.549,"Chl a (µg/L)","biomass","biom","SS",NA,2.342,NA,1.656,2,19,NA,13.6,NA,0.459,"Chl a (µg/L)",2,NA,0.18,NA,0.127,2,0.571,1.661,-3.472,2.507
"983",983,999,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 3","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.298,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.047,NA,0.027,3,65,NA,46.4,NA,0.222,"Growth rate (µ/d)",2,NA,0.047,NA,0.027,3,0.8,0.047,-1.305,0.809
"984",984,1000,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 3","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.411,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.049,NA,0.028,3,65,NA,46.4,NA,0.338,"Growth rate (µ/d)",2,NA,0.059,NA,0.034,3,0.8,0.054,-1.076,0.763
"985",985,1001,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 3","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","9",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.298,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.047,NA,0.027,3,19,NA,13.6,NA,-0.049,"Growth rate (µ/d)",2,NA,0.047,NA,0.027,3,0.8,0.047,-5.944,3.611
"986",986,1002,"489","Wetz, MS; Wheeler, PA; Letelier, RM",2004,"Light-induced growth of phytoplankton collected during the winter from the benthic boundary layer off Oregon, USA","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Figure 3","winter","2003","Lab","coastal",45,-124.12,"Oregon Coast, USA","Total phytoplankton","phytoplankton",NA,"in situ incubation","Polystyrene tissue culture flasks",1.5,NA,"yes","none","reduced light","12",NA,NA,10,NA,NA,NA,NA,NA,NA,NA,NA,0,140,NA,100,NA,0.411,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.049,NA,0.028,3,19,NA,13.6,NA,0.016,"Growth rate (µ/d)",2,NA,0.055,NA,0.032,3,0.8,0.052,-6.075,3.743
"987",987,1003,"499","Goldman, JC; McGillicuddy, DJ",2003,"Effect of large marine diatoms growing at low light on episodic new production","LIMNOLOGY AND OCEANOGRAPHY",1,NA,"The number of replicates is not given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"988",988,1004,"505","Maclean, C; Cembella, AD; Quilliam, MA",2003,"Effects of light, salinity and inorganic nitrogen on cell growth and spirolide production in the marine dinoflagellate Alexandrium ostenfeldii (Paulsen) Balech et Tangen","BOTANICA MARINA",1,NA,NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Alexandrium ostenfeldii","phytoplankton",30,"microcosm","borosilicate glass tubes",0.03,NA,"no","nutrients","reduced light","14",NA,NA,14,NA,NA,29,36.3,880,36.3,880,NA,4,150,NA,100,NA,0.05,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.05,NA,0.029,3,40,NA,26.7,NA,0.13,"Growth rate (µ/d)",2,NA,0.03,NA,0.017,3,0.8,0.041,1.552,0.867
"989",989,1005,"505","Maclean, C; Cembella, AD; Quilliam, MA",2003,"Effects of light, salinity and inorganic nitrogen on cell growth and spirolide production in the marine dinoflagellate Alexandrium ostenfeldii (Paulsen) Balech et Tangen","BOTANICA MARINA",1,NA,NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Alexandrium ostenfeldii","phytoplankton",30,"microcosm","borosilicate glass tubes",0.03,NA,"no","nutrients","reduced light","14",NA,NA,14,NA,NA,29,36.3,880,36.3,880,NA,4,150,NA,100,NA,0.05,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.05,NA,0.029,3,70,NA,46.7,NA,0.12,"Growth rate (µ/d)",2,NA,0.03,NA,0.017,3,0.8,0.041,1.358,0.82
"990",990,1006,"505","Maclean, C; Cembella, AD; Quilliam, MA",2003,"Effects of light, salinity and inorganic nitrogen on cell growth and spirolide production in the marine dinoflagellate Alexandrium ostenfeldii (Paulsen) Balech et Tangen","BOTANICA MARINA",1,NA,NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Alexandrium ostenfeldii","phytoplankton",30,"microcosm","borosilicate glass tubes",0.03,NA,"no","nutrients","reduced light","14",NA,NA,14,NA,NA,29,36.3,880,36.3,880,NA,4,150,NA,100,NA,0.05,"Growth rate (µ/d)","growth rate","biom","dSS",NA,0.05,NA,0.029,3,100,NA,66.7,NA,0.26,"Growth rate (µ/d)",2,NA,0.02,NA,0.012,3,0.8,0.038,4.412,2.289
"991",991,1007,"513","Floder, S; Urabe, J; Kawabata, Z",2002,"The influence of fluctuating light intensities on species composition and diversity of natural phytoplankton communities","OECOLOGIA",2,"closely related freshwater study","freshwater, no extractable data",NA,NA,NA,"Lab",NA,35,136,"Lake Biwa, Japan","phytoplankton","phytoplankton",49,"microcosm","Erlenmeyer flask",300,NA,"unknown","interval","constant light","16",NA,NA,20,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"992",992,1009,"518","Agawin, NSR; Agusti, S; Duarte, CM",2002,"Abundance of Antarctic picophytoplankton and their response to light and nutrient manipulation","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table 2","winter","2000","Field","coastal",-62.4,-60.22,"Johnson Cove, Antarctica","picophytoplankton  <2µm","phytoplankton",9,"mesocosm","polyethene bags",25000,NA,"yes","nutrients","shading screen","natural",NA,"PAR",NA,NA,NA,NA,1.52,24.6,1.52,24.6,NA,4,NA,NA,100,NA,10.8,"primary production (mg C /m3/d)","area-specific production","biom","dSS",NA,1.98,NA,1.4,2,NA,NA,25,NA,11.4,"primary production (mg C /m3/d)",1,NA,2.1,NA,1.5,2,0.571,2.052,0.167,1.003
"993",993,1011,"518","Agawin, NSR; Agusti, S; Duarte, CM",2002,"Abundance of Antarctic picophytoplankton and their response to light and nutrient manipulation","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table 2","winter","2000","Field","coastal",-62.4,-60.22,"Johnson Cove, Antarctica","picophytoplankton  <2µm","phytoplankton",9,"mesocosm","polyethene bags",25000,NA,"yes","nutrients","shading screen","natural",NA,"PAR",NA,NA,NA,NA,1.52,24.6,1.52,24.6,NA,4,NA,NA,100,NA,1.2,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,0.141,NA,0.1,2,NA,NA,25,NA,1.5,"specific primary production (mg C /mg C/d)",1,NA,0.3,NA,0.2,2,0.571,0.224,0.767,1.073
"994",994,1008,"518","Agawin, NSR; Agusti, S; Duarte, CM",2002,"Abundance of Antarctic picophytoplankton and their response to light and nutrient manipulation","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table 2","winter","2000","Field","coastal",-62.4,-60.22,"Johnson Cove, Antarctica","picophytoplankton  <2µm","phytoplankton",16,"mesocosm","polyethene bags",25000,NA,"yes","nutrients","shading screen","natural",NA,"PAR",NA,NA,NA,NA,1.62,27.48,1.62,27.48,NA,4,NA,NA,100,NA,18.8,"primary production (mg C /m3/d)","area-specific production","biom","dSS",NA,5.94,NA,4.2,2,NA,NA,25,NA,14.3,"primary production (mg C /m3/d)",1,NA,1.6,NA,1.1,2,0.571,4.342,-0.592,1.044
"995",995,1010,"518","Agawin, NSR; Agusti, S; Duarte, CM",2002,"Abundance of Antarctic picophytoplankton and their response to light and nutrient manipulation","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table 2","winter","2000","Field","coastal",-62.4,-60.22,"Johnson Cove, Antarctica","picophytoplankton  <2µm","phytoplankton",16,"mesocosm","polyethene bags",25000,NA,"yes","nutrients","shading screen","natural",NA,"PAR",NA,NA,NA,NA,1.62,27.48,1.62,27.48,NA,4,NA,NA,100,NA,3.3,"specific primary production (mg C /mg C/d)","mass-specific production","phys","dQ",NA,1.273,NA,0.9,2,NA,NA,25,NA,1.4,"specific primary production (mg C /mg C/d)",1,NA,0.1,NA,0.1,2,0.571,0.906,-1.199,1.18
"996",996,1012,"534","Holmer, M; Laursen, L",2002,"Effect of shading of Zostera marina (eelgrass) on sulfur cycling in sediments with contrasting organic matter and sulfide pools","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Eelgrass Zostera marina, 1 week acclimatisation",NA,"Fig 1","fall","1999","Lab","coastal",NA,NA,"Fyn, Denmark","Zostera marina","seagrass",14,"mesocosm","Aquaria",100,NA,"unknown","none",NA,NA,NA,NA,15,NA,NA,13.5,NA,NA,NA,NA,NA,0,197.5,NA,100,NA,123.5,"Above ground Biomass (gdw/m2)","biomass","biom","SS",NA,5.196,NA,3,3,22.5,NA,11.4,NA,83.6,"Above ground Biomass (gdw/m2)",2,NA,1.9,NA,1.1,3,0.8,3.913,-8.157,6.211
"997",997,1013,"534","Holmer, M; Laursen, L",2002,"Effect of shading of Zostera marina (eelgrass) on sulfur cycling in sediments with contrasting organic matter and sulfide pools","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Eelgrass Zostera marina, 1 week acclimatisation",NA,"Fig 1","spring","1999","Lab","coastal",NA,NA,"Fyn, Denmark","Zostera marina","seagrass",14,"mesocosm","Aquaria",100,NA,"unknown","none",NA,NA,NA,NA,15,NA,NA,13.5,NA,NA,NA,NA,NA,0,197.5,NA,100,NA,122.2,"Above ground Biomass (gdw/m2)","biomass","biom","SS",NA,48.497,NA,28,3,22.5,NA,11.4,NA,41.1,"Above ground Biomass (gdw/m2)",2,NA,31.5,NA,18.2,3,0.8,40.901,-1.586,0.876
"998",998,1014,"534","Holmer, M; Laursen, L",2002,"Effect of shading of Zostera marina (eelgrass) on sulfur cycling in sediments with contrasting organic matter and sulfide pools","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Eelgrass Zostera marina, 1 week acclimatisation","NO std or ste for ctrl","Fig 1","Spring","2000","Lab","coastal",NA,NA,"Fyn, Denmark","Zostera marina","seagrass",14,"mesocosm","Aquaria",100,NA,"unknown","none",NA,NA,NA,NA,15,NA,NA,13.5,NA,NA,NA,NA,NA,0,197.5,NA,100,NA,44.4,"Above ground Biomass (gdw/m2)","biomass","biom","SS",NA,NA,NA,NA,3,22.5,NA,11.4,NA,29.5,"Above ground Biomass (gdw/m2)",2,NA,20.6,NA,11.9,3,0.8,NA,NA,NA
"999",999,1015,"534","Holmer, M; Laursen, L",2002,"Effect of shading of Zostera marina (eelgrass) on sulfur cycling in sediments with contrasting organic matter and sulfide pools","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Eelgrass Zostera marina, 1 week acclimatisation",NA,"Fig 1","fall","1999","Lab","coastal",NA,NA,"Fyn, Denmark","Zostera marina","seagrass",14,"mesocosm","Aquaria",100,NA,"unknown","none",NA,NA,NA,NA,15,NA,NA,13.5,NA,NA,NA,NA,NA,0,197.5,NA,100,NA,0.02,"relative leaf elongation (mm/mm/d)","growth rate","biom","dSS",NA,0.014,NA,0.008,3,22.5,NA,11.4,NA,0.022,"relative leaf elongation (mm/mm/d)",2,NA,0.009,NA,0.005,3,0.8,0.012,0.118,0.668
"1000",1000,1016,"534","Holmer, M; Laursen, L",2002,"Effect of shading of Zostera marina (eelgrass) on sulfur cycling in sediments with contrasting organic matter and sulfide pools","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Eelgrass Zostera marina, 1 week acclimatisation",NA,"Fig 1","spring","1999","Lab","coastal",NA,NA,"Fyn, Denmark","Zostera marina","seagrass",14,"mesocosm","Aquaria",100,NA,"unknown","none",NA,NA,NA,NA,15,NA,NA,13.5,NA,NA,NA,NA,NA,0,197.5,NA,100,NA,0.029,"relative leaf elongation (mm/mm/d)","growth rate","biom","dSS",NA,0.003,NA,0.002,3,22.5,NA,11.4,NA,0.018,"relative leaf elongation (mm/mm/d)",2,NA,0.007,NA,0.004,3,0.8,0.005,-1.504,0.855
"1001",1001,1017,"534","Holmer, M; Laursen, L",2002,"Effect of shading of Zostera marina (eelgrass) on sulfur cycling in sediments with contrasting organic matter and sulfide pools","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Eelgrass Zostera marina, 1 week acclimatisation",NA,"Fig 1","spring","2000","Lab","coastal",NA,NA,"Fyn, Denmark","Zostera marina","seagrass",14,"mesocosm","Aquaria",100,NA,"unknown","none",NA,NA,NA,NA,15,NA,NA,13.5,NA,NA,NA,NA,NA,0,197.5,NA,100,NA,0.023,"relative leaf elongation (mm/mm/d)","growth rate","biom","dSS",NA,0.007,NA,0.004,3,22.5,NA,11.4,NA,0.01,"relative leaf elongation (mm/mm/d)",2,NA,0.001,NA,0.001,3,0.8,0.005,-2.123,1.042
"1002",1002,1018,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,2.03,"Leaf elongation rate (cm plant/d)","growth rate","biom","dSS",NA,0.209,NA,0.148,2,NA,20.6,41.8,NA,2.876,"Leaf elongation rate (cm plant/d)",2,NA,0.373,NA,0.264,2,0.571,0.303,1.597,1.319
"1003",1003,1019,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,2.03,"Leaf elongation rate (cm plant/d)","growth rate","biom","dSS",NA,0.209,NA,0.148,2,NA,3.6,7.3,NA,1.819,"Leaf elongation rate (cm plant/d)",2,NA,0.148,NA,0.105,2,0.571,0.181,-0.664,1.055
"1004",1004,1020,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,2.03,"Leaf elongation rate (cm plant/d)","growth rate","biom","dSS",NA,0.209,NA,0.148,2,NA,0.6,1.2,NA,0.698,"Leaf elongation rate (cm plant/d)",2,NA,0.223,NA,0.158,2,0.571,0.216,-3.516,2.545
"1005",1005,1021,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.326,"Leaf appearance rate (leaves/plant/d)","growth rate","biom","dSS",NA,0.082,NA,0.058,2,NA,20.6,41.8,NA,0.388,"Leaf appearance rate (leaves/plant/d)",2,NA,0.069,NA,0.049,2,0.571,0.076,0.467,1.027
"1006",1006,1022,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.326,"Leaf appearance rate (leaves/plant/d)","growth rate","biom","dSS",NA,0.082,NA,0.058,2,NA,3.6,7.3,NA,0.169,"Leaf appearance rate (leaves/plant/d)",2,NA,0.055,NA,0.039,2,0.571,0.07,-1.284,1.206
"1007",1007,1023,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.326,"Leaf appearance rate (leaves/plant/d)","growth rate","biom","dSS",NA,0.082,NA,0.058,2,NA,0.6,1.2,NA,0.072,"Leaf appearance rate (leaves/plant/d)",2,NA,0.047,NA,0.033,2,0.571,0.067,-2.175,1.591
"1008",1008,1024,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start","All values not available","Fig 2","Fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.296,"Leaf loss rate (cm/plant/d)","growth rate","biom","dSS",NA,0.239,NA,0.169,2,NA,20.6,41.8,NA,NA,"Leaf loss rate (cm/plant/d)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"1009",1009,1025,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.296,"Leaf loss rate (cm/plant/d)","growth rate","biom","dSS",NA,0.239,NA,0.169,2,NA,3.6,7.3,NA,0.476,"Leaf loss rate (cm/plant/d)",2,NA,0.269,NA,0.19,2,0.571,0.254,0.404,1.02
"1010",1010,1026,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 2","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.296,"Leaf loss rate (cm/plant/d)","growth rate","biom","dSS",NA,0.239,NA,0.169,2,NA,0.6,1.2,NA,2.686,"Leaf loss rate (cm/plant/d)",2,NA,0.808,NA,0.571,2,0.571,0.595,2.293,1.657
"1011",1011,1027,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 3","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.143,"Internode elongation rate (cm/d)","growth rate","biom","dSS",NA,0.016,NA,0.011,2,NA,20.6,41.8,NA,0.165,"Internode elongation rate (cm/d)",2,NA,0.008,NA,0.006,2,0.571,0.013,1.003,1.126
"1012",1012,1028,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 3","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.143,"Internode elongation rate (cm/d)","growth rate","biom","dSS",NA,0.016,NA,0.011,2,NA,3.6,7.3,NA,0.102,"Internode elongation rate (cm/d)",2,NA,0.018,NA,0.013,2,0.571,0.017,-1.376,1.237
"1013",1013,1029,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 3","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.143,"Internode elongation rate (cm/d)","growth rate","biom","dSS",NA,0.016,NA,0.011,2,NA,0.6,1.2,NA,0.032,"Internode elongation rate (cm/d)",2,NA,0.007,NA,0.005,2,0.571,0.012,-5.249,4.445
"1014",1014,1030,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 3","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.105,"Internode appearance rate (internodes/d)","growth rate","biom","dSS",NA,0.013,NA,0.009,2,NA,20.6,41.8,NA,0.157,"Internode appearance rate (internodes/d)",2,NA,0.033,NA,0.023,2,0.571,0.025,1.203,1.181
"1015",1015,1031,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 3","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.105,"Internode appearance rate (internodes/d)","growth rate","biom","dSS",NA,0.013,NA,0.009,2,NA,3.6,7.3,NA,0.073,"Internode appearance rate (internodes/d)",2,NA,0.01,NA,0.007,2,0.571,0.011,-1.604,1.322
"1016",1016,1032,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 3","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.105,"Internode appearance rate (internodes/d)","growth rate","biom","dSS",NA,0.013,NA,0.009,2,NA,0.6,1.2,NA,0.011,"Internode appearance rate (internodes/d)",2,NA,0.01,NA,0.007,2,0.571,0.011,-4.711,3.774
"1017",1017,1033,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 4","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.452,"root elongation rate (cm/d)","growth rate","biom","dSS",NA,0.068,NA,0.048,2,NA,20.6,41.8,NA,0.644,"root elongation rate (cm/d)",2,NA,0.071,NA,0.05,2,0.571,0.069,1.583,1.313
"1018",1018,1034,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 4","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.452,"root elongation rate (cm/d)","growth rate","biom","dSS",NA,0.068,NA,0.048,2,NA,3.6,7.3,NA,0.283,"root elongation rate (cm/d)",2,NA,0.082,NA,0.058,2,0.571,0.075,-1.283,1.206
"1019",1019,1035,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 4","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.452,"root elongation rate (cm/d)","growth rate","biom","dSS",NA,0.068,NA,0.048,2,NA,0.6,1.2,NA,0.017,"root elongation rate (cm/d)",2,NA,0.034,NA,0.024,2,0.571,0.054,-4.632,3.682
"1020",1020,1036,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 4","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.313,"root appearance rate (roots/d)","growth rate","biom","dSS",NA,0.044,NA,0.031,2,NA,20.6,41.8,NA,0.387,"root appearance rate (roots/d)",2,NA,0.042,NA,0.03,2,0.571,0.043,0.98,1.12
"1021",1021,1037,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 4","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.313,"root appearance rate (roots/d)","growth rate","biom","dSS",NA,0.044,NA,0.031,2,NA,3.6,7.3,NA,0.21,"root appearance rate (roots/d)",2,NA,0.051,NA,0.036,2,0.571,0.048,-1.239,1.192
"1022",1022,1038,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start","All values not available","Fig 4","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,0.313,"root appearance rate (roots/d)","growth rate","biom","dSS",NA,0.044,NA,0.031,2,NA,0.6,1.2,NA,NA,"root appearance rate (roots/d)",2,NA,NA,NA,NA,2,0.571,NA,NA,NA
"1023",1023,1039,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 5","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,1.582,"Growth rate (mgdw plant/d)","growth rate","biom","dSS",NA,0.362,NA,0.256,2,NA,20.6,41.8,NA,2.382,"Growth rate (mgdw plant/d)",2,NA,0.303,NA,0.214,2,0.571,0.334,1.37,1.235
"1024",1024,1040,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 5","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,1.582,"Growth rate (mgdw plant/d)","growth rate","biom","dSS",NA,0.362,NA,0.256,2,NA,3.6,7.3,NA,1.088,"Growth rate (mgdw plant/d)",2,NA,0.116,NA,0.082,2,0.571,0.269,-1.05,1.138
"1025",1025,1041,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 5","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,1.582,"Growth rate (mgdw plant/d)","growth rate","biom","dSS",NA,0.362,NA,0.256,2,NA,0.6,1.2,NA,-0.099,"Growth rate (mgdw plant/d)",2,NA,0.129,NA,0.091,2,0.571,0.272,-3.536,2.562
"1026",1026,1042,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,117,"Sucrose (above ground Biomass mg/gdw)","cellular content","phys","Q",NA,22.6,NA,16,2,NA,20.6,41.8,NA,162,"Sucrose (above ground Biomass mg/gdw)",2,NA,11.3,NA,8,2,0.571,17.889,1.437,1.258
"1027",1027,1043,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,117,"Sucrose (above ground Biomass mg/gdw)","cellular content","phys","Q",NA,22.6,NA,16,2,NA,3.6,7.3,NA,121,"Sucrose (above ground Biomass mg/gdw)",2,NA,41,NA,29,2,0.571,33.121,0.069,1.001
"1028",1028,1044,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,117,"Sucrose (above ground Biomass mg/gdw)","cellular content","phys","Q",NA,22.6,NA,16,2,NA,0.6,1.2,NA,98,"Sucrose (above ground Biomass mg/gdw)",2,NA,9.9,NA,7,2,0.571,17.464,-0.622,1.048
"1029",1029,1045,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,235,"Sucrose (below ground Biomass mg/gdw)","cellular content","phys","Q",NA,26.9,NA,19,2,NA,20.6,41.8,NA,240,"Sucrose (below ground Biomass mg/gdw)",2,NA,60.8,NA,43,2,0.571,47.011,0.061,1
"1030",1030,1046,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,235,"Sucrose (below ground Biomass mg/gdw)","cellular content","phys","Q",NA,26.9,NA,19,2,NA,3.6,7.3,NA,85,"Sucrose (below ground Biomass mg/gdw)",2,NA,8.5,NA,6,2,0.571,19.925,-4.302,3.313
"1031",1031,1047,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,235,"Sucrose (below ground Biomass mg/gdw)","cellular content","phys","Q",NA,26.9,NA,19,2,NA,0.6,1.2,NA,95,"Sucrose (below ground Biomass mg/gdw)",2,NA,15.6,NA,11,2,0.571,21.954,-3.644,2.66
"1032",1032,1048,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,3.94,"Starch (above ground Biomass mg/gdw)","cellular content","phys","Q",NA,0.523,NA,0.37,2,NA,20.6,41.8,NA,3.27,"Starch (above ground Biomass mg/gdw)",2,NA,0.438,NA,0.31,2,0.571,0.483,-0.793,1.079
"1033",1033,1049,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,3.94,"Starch (above ground Biomass mg/gdw)","cellular content","phys","Q",NA,0.523,NA,0.37,2,NA,3.6,7.3,NA,1.57,"Starch (above ground Biomass mg/gdw)",2,NA,0.354,NA,0.25,2,0.571,0.447,-3.033,2.15
"1034",1034,1050,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,3.94,"Starch (above ground Biomass mg/gdw)","cellular content","phys","Q",NA,0.523,NA,0.37,2,NA,0.6,1.2,NA,1.79,"Starch (above ground Biomass mg/gdw)",2,NA,0.58,NA,0.41,2,0.571,0.552,-2.225,1.619
"1035",1035,1051,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,3.63,"Starch (below ground Biomass mg/gdw)","cellular content","phys","Q",NA,0.849,NA,0.6,2,NA,20.6,41.8,NA,3.73,"Starch (below ground Biomass mg/gdw)",2,NA,0.509,NA,0.36,2,0.571,0.7,0.082,1.001
"1036",1036,1052,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,3.63,"Starch (below ground Biomass mg/gdw)","cellular content","phys","Q",NA,0.849,NA,0.6,2,NA,3.6,7.3,NA,3.35,"Starch (below ground Biomass mg/gdw)",2,NA,1.188,NA,0.84,2,0.571,1.032,-0.155,1.003
"1037",1037,1053,"535","Peralta, G; Perez-Llorens, JL; Hernandez, I; Vergara, JJ",2002,"Effects of light availability on growth, architecture and nutrient content of the seagrass Zostera noltii Hornem.","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass Zostera noltii, 24h natural irradiance acclimation prior experiment start",NA,"Fig 7","fall",NA,"Lab","coastal",36.5,-6.17,"Rio San Pedro, Spain","Zostera noltii","seagrass",14,"mesocosm","Aquaria",50,NA,"unknown","none","shading screen","11",NA,"PAR",18.5,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,49.3,100,NA,3.63,"Starch (below ground Biomass mg/gdw)","cellular content","phys","Q",NA,0.849,NA,0.6,2,NA,0.6,1.2,NA,4.99,"Starch (below ground Biomass mg/gdw)",2,NA,0.495,NA,0.35,2,0.571,0.695,1.119,1.156
"1038",1038,1054,"537","Stramski, D; Sciandra, A; Claustre, H",2002,"Effects of temperature, nitrogen, and light limitation on the optical properties of the marine diatom Thalassiosira pseudonana","LIMNOLOGY AND OCEANOGRAPHY",1,NA,"No comparable treatments",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1039",1039,1055,"545","Rost, B; Zondervan, I; Riebesell, U",2002,"Light-dependent carbon isotope fractionation in the coccolithophorid Emiliania huxleyi","LIMNOLOGY AND OCEANOGRAPHY",1,NA,"data comparison not possible, different CO2 values for all light treatments",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1040",1040,1056,"555","Vasuki, S; Ganesan, M; Rao, PVS",2001,"Effect of light intensity, photoperiod, ESP medium and nitrogen sources on growth of marine brown alga Padina boergesenii (Dictyotales, Phaeophyta)","INDIAN JOURNAL OF MARINE SCIENCES",1,"marine brown alga Padina boergesenii","STD, STE not specified",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1041",1041,1063,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","spring","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",20,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,1.034,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.05,NA,0.028,3,NA,3.5,63.6,NA,0.827,"Shoot mass (g/shoot)",2,NA,0.056,NA,0.023,6,0.889,0.054,-3.394,1.14
"1042",1042,1072,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances, only 38 and 17% shading",NA,"Fig 5","spring","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",20,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,7.302,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.49,NA,0.202,6,NA,3.5,63.6,NA,4.927,"shoot growth rate (gdw/shoot/d)",2,NA,0.495,NA,0.202,6,0.923,0.495,-4.431,1.151
"1043",1043,1081,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances, only 38 and 17% shading",NA,"Fig 5","spring","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",20,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,4.3,"leaves/shoot","abundance","biom","SS",NA,0.35,NA,0.143,6,NA,3.5,63.6,NA,4.791,"leaves/shoot",2,NA,0.38,NA,0.155,6,0.923,0.365,1.241,0.397
"1044",1044,1057,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","spring","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",30,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,1.254,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.09,NA,0.051,3,NA,3.5,63.6,NA,0.843,"Shoot mass (g/shoot)",2,NA,0.164,NA,0.067,6,0.889,0.147,-2.493,0.845
"1045",1045,1058,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","spring","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",30,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,1.254,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.09,NA,0.051,3,NA,1.8,31.8,NA,0.978,"Shoot mass (g/shoot)",2,NA,0.387,NA,0.158,6,0.889,0.33,-0.742,0.531
"1046",1046,1066,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","spring","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",30,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,6.614,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.93,NA,0.38,6,NA,3.5,63.6,NA,5.047,"shoot growth rate (gdw/shoot/d)",2,NA,0.803,NA,0.328,6,0.923,0.868,-1.666,0.449
"1047",1047,1067,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","spring","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",30,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,6.614,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.93,NA,0.38,6,NA,1.8,31.8,NA,4.693,"shoot growth rate (gdw/shoot/d)",2,NA,2.352,NA,0.96,6,0.923,1.788,-0.992,0.374
"1048",1048,1075,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","spring","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",30,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,4.271,"leaves/shoot","abundance","biom","SS",NA,0.18,NA,0.072,6,NA,3.5,63.6,NA,3.814,"leaves/shoot",2,NA,0.336,NA,0.137,6,0.923,0.268,-1.574,0.437
"1049",1049,1076,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","spring","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",30,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,5.5,100,NA,4.271,"leaves/shoot","abundance","biom","SS",NA,0.18,NA,0.072,6,NA,1.8,31.8,NA,3.42,"leaves/shoot",2,NA,0.377,NA,0.154,6,0.923,0.294,-2.668,0.63
"1050",1050,1064,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","summer","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",50,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,0.798,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.08,NA,0.045,3,NA,9.2,64.3,NA,0.761,"Shoot mass (g/shoot)",2,NA,0.14,NA,0.057,6,0.889,0.125,-0.263,0.504
"1051",1051,1073,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances, only 38 and 17% shading",NA,"Fig 5","summer","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",50,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,5.085,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.74,NA,0.303,6,NA,9.2,64.3,NA,3.721,"shoot growth rate (gdw/shoot/d)",2,NA,0.556,NA,0.227,6,0.923,0.656,-1.92,0.487
"1052",1052,1082,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances, only 38 and 17% shading",NA,"Fig 5","summer","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",50,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,3.6,"leaves/shoot","abundance","biom","SS",NA,0.46,NA,0.186,6,NA,9.2,64.3,NA,3.9,"leaves/shoot",2,NA,0.377,NA,0.154,6,0.923,0.418,0.662,0.352
"1053",1053,1059,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",60,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,1.366,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.21,NA,0.119,3,NA,9.2,64.3,NA,0.732,"Shoot mass (g/shoot)",2,NA,0.027,NA,0.011,6,0.889,0.113,-5.009,1.894
"1054",1054,1060,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",60,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,1.366,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.21,NA,0.119,3,NA,5.4,37.8,NA,0.844,"Shoot mass (g/shoot)",2,NA,0.083,NA,0.034,6,0.889,0.131,-3.549,1.2
"1055",1055,1068,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",60,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,5.965,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.93,NA,0.38,6,NA,9.2,64.3,NA,3.008,"shoot growth rate (gdw/shoot/d)",2,NA,1.732,NA,0.707,6,0.923,1.389,-1.965,0.494
"1056",1056,1069,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",60,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,5.965,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.93,NA,0.38,6,NA,5.4,37.8,NA,2.856,"shoot growth rate (gdw/shoot/d)",2,NA,0.867,NA,0.354,6,0.923,0.898,-3.195,0.759
"1057",1057,1077,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",60,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,4.414,"leaves/shoot","abundance","biom","SS",NA,0.53,NA,0.215,6,NA,9.2,64.3,NA,3.317,"leaves/shoot",2,NA,0.169,NA,0.069,6,0.923,0.391,-2.589,0.613
"1058",1058,1078,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",60,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,14.3,100,NA,4.414,"leaves/shoot","abundance","biom","SS",NA,0.53,NA,0.215,6,NA,5.4,37.8,NA,3.094,"leaves/shoot",2,NA,0.336,NA,0.137,6,0.923,0.442,-2.759,0.651
"1059",1059,1065,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","summer","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",90,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,0.682,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.07,NA,0.043,3,NA,8.2,62.1,NA,0.402,"Shoot mass (g/shoot)",2,NA,0.069,NA,0.028,6,0.889,0.07,-3.539,1.196
"1060",1060,1074,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances, only 38 and 17% shading",NA,"Fig 5","summer","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",90,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,3.222,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,0.43,NA,0.176,6,NA,8.2,62.1,NA,2.185,"shoot growth rate (gdw/shoot/d)",2,NA,0.558,NA,0.228,6,0.923,0.499,-1.919,0.487
"1061",1061,1083,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances, only 38 and 17% shading",NA,"Fig 5","summer","1995","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",90,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,3.586,"leaves/shoot","abundance","biom","SS",NA,0.35,NA,0.143,6,NA,8.2,62.1,NA,2.494,"leaves/shoot",2,NA,0.294,NA,0.12,6,0.923,0.323,-3.117,0.738
"1062",1062,1061,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",105,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,0.82,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.13,NA,0.073,3,NA,8.2,62.1,NA,0.639,"Shoot mass (g/shoot)",2,NA,0.164,NA,0.067,6,0.889,0.154,-1.043,0.56
"1063",1063,1062,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",105,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,0.82,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.13,NA,0.073,3,NA,4.9,37.1,NA,0.396,"Shoot mass (g/shoot)",2,NA,0.056,NA,0.023,6,0.889,0.083,-4.559,1.655
"1064",1064,1070,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",105,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,3.5,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,1.36,NA,0.56,6,NA,8.2,62.1,NA,2.186,"shoot growth rate (gdw/shoot/d)",2,NA,0.37,NA,0.151,6,0.923,0.998,-1.215,0.395
"1065",1065,1071,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances 38, 17 and 10%",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",105,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,3.5,"shoot growth rate (gdw/shoot/d)","growth rate","biom","dSS",NA,1.36,NA,0.56,6,NA,4.9,37.1,NA,1.225,"shoot growth rate (gdw/shoot/d)",2,NA,0.311,NA,0.127,6,0.923,0.988,-2.126,0.522
"1066",1066,1079,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",105,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,3.5,"leaves/shoot","abundance","biom","SS",NA,0.52,NA,0.214,6,NA,8.2,62.1,NA,2.494,"leaves/shoot",2,NA,0.294,NA,0.12,6,0.923,0.425,-2.185,0.532
"1067",1067,1080,"578","Ruiz, JM; Romero, J",2001,"Effects of in situ experimental shading on the Mediterranean seagrass Posidonia oceanica","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, irradiance values at canopy level, as % of surface irradiances",NA,"Fig 5","summer","1993","Field","coastal",37.41,-1.55,"Fraile Island, Spain","Posidonia oceanica","seagrass",105,"field plot","no container",NA,0.0625,"yes","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,13.2,100,NA,3.5,"leaves/shoot","abundance","biom","SS",NA,0.52,NA,0.214,6,NA,4.9,37.1,NA,2.1,"leaves/shoot",2,NA,0.169,NA,0.069,6,0.923,0.389,-3.318,0.792
"1068",1068,1084,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,103.989,"leaf soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,87.83,NA,39.28,5,NA,NA,9,NA,60.584,"leaf soluble carbohydrates (mmol sucrose/gdw)",1,NA,31.511,NA,14.092,5,0.903,65.983,-0.594,0.418
"1069",1069,1087,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,225.853,"rhizome soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,93.03,NA,41.605,5,NA,NA,9,NA,232.799,"rhizome soluble carbohydrates (mmol sucrose/gdw)",1,NA,80.566,NA,36.03,5,0.903,87.022,0.072,0.4
"1070",1070,1090,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,76.203,"root soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,36.9,NA,16.502,5,NA,NA,9,NA,98.87,"root soluble carbohydrates (mmol sucrose/gdw)",1,NA,49.211,NA,22.008,5,0.903,43.493,0.471,0.411
"1071",1071,1093,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,149.915,"leaf soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,20.35,NA,9.1,5,NA,NA,5.1,NA,71.403,"leaf soluble carbohydrates (mmol sucrose/gdw)",1,NA,26.793,NA,11.982,5,0.903,23.79,-2.981,0.844
"1072",1072,1096,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,343.099,"rhizome soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,53.07,NA,23.732,5,NA,NA,5.1,NA,317.87,"rhizome soluble carbohydrates (mmol sucrose/gdw)",1,NA,50.159,NA,22.432,5,0.903,51.633,-0.441,0.41
"1073",1073,1099,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,125.592,"root soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,35.46,NA,15.859,5,NA,NA,5.1,NA,86.962,"root soluble carbohydrates (mmol sucrose/gdw)",1,NA,41.631,NA,18.618,5,0.903,38.67,-0.902,0.441
"1074",1074,1102,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 4","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,2.369,"Shoot growth rate (mm/d)","growth rate","biom","dSS",NA,1.252,NA,0.56,5,NA,NA,9,NA,1.482,"Shoot growth rate (mm/d)",2,NA,1.25,NA,0.559,5,0.903,1.251,-0.64,0.421
"1075",1075,1105,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 4","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",7,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,6.133,"Shoot growth rate (mm/d)","growth rate","biom","dSS",NA,2.2,NA,0.984,5,NA,NA,5.1,NA,6.084,"Shoot growth rate (mm/d)",2,NA,3.079,NA,1.377,5,0.903,2.676,-0.017,0.4
"1076",1076,1085,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,166.383,"leaf soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,85.5,NA,38.237,5,NA,NA,9,NA,71.717,"leaf soluble carbohydrates (mmol sucrose/gdw)",1,NA,27.009,NA,12.079,5,0.903,63.403,-1.349,0.491
"1077",1077,1088,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,382.55,"rhizome soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,170.5,NA,76.248,5,NA,NA,9,NA,356.18,"rhizome soluble carbohydrates (mmol sucrose/gdw)",1,NA,93.063,NA,41.619,5,0.903,137.349,-0.173,0.402
"1078",1078,1091,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,64.713,"root soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,35.32,NA,15.795,5,NA,NA,9,NA,82.579,"root soluble carbohydrates (mmol sucrose/gdw)",1,NA,38.456,NA,17.198,5,0.903,36.921,0.437,0.41
"1079",1079,1094,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,179.124,"leaf soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,24.61,NA,11.004,5,NA,NA,5.1,NA,64.228,"leaf soluble carbohydrates (mmol sucrose/gdw)",1,NA,20.315,NA,9.085,5,0.903,22.562,-4.6,1.458
"1080",1080,1097,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,388.266,"rhizome soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,37.52,NA,16.78,5,NA,NA,5.1,NA,304.307,"rhizome soluble carbohydrates (mmol sucrose/gdw)",1,NA,37.521,NA,16.78,5,0.903,37.521,-2.021,0.604
"1081",1081,1100,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,67.88,"root soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,23.13,NA,10.345,5,NA,NA,5.1,NA,75.469,"root soluble carbohydrates (mmol sucrose/gdw)",1,NA,30.831,NA,13.788,5,0.903,27.255,0.252,0.403
"1082",1082,1103,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 4","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,1.986,"Shoot growth rate (mm/d)","growth rate","biom","dSS",NA,0.809,NA,0.362,5,NA,NA,9,NA,1.624,"Shoot growth rate (mm/d)",2,NA,1.25,NA,0.559,5,0.903,1.053,-0.311,0.405
"1083",1083,1106,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 4","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",14,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,7.185,"Shoot growth rate (mm/d)","growth rate","biom","dSS",NA,1.32,NA,0.589,5,NA,NA,5.1,NA,5.659,"Shoot growth rate (mm/d)",2,NA,3.298,NA,1.475,5,0.903,2.511,-0.549,0.415
"1084",1084,1086,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,83.747,"leaf soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,53.97,NA,24.134,5,NA,NA,9,NA,120.129,"leaf soluble carbohydrates (mmol sucrose/gdw)",1,NA,49.518,NA,22.145,5,0.903,51.789,0.635,0.42
"1085",1085,1089,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,188.389,"rhizome soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,18.57,NA,8.304,5,NA,NA,9,NA,221.675,"rhizome soluble carbohydrates (mmol sucrose/gdw)",1,NA,71.234,NA,31.857,5,0.903,52.053,0.578,0.417
"1086",1086,1092,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 3","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,38.802,"root soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,43.04,NA,19.25,5,NA,NA,9,NA,34.688,"root soluble carbohydrates (mmol sucrose/gdw)",1,NA,9.219,NA,4.123,5,0.903,31.127,-0.119,0.401
"1087",1087,1095,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,159.489,"leaf soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,36.43,NA,16.29,5,NA,NA,5.1,NA,103.963,"leaf soluble carbohydrates (mmol sucrose/gdw)",1,NA,24.617,NA,11.009,5,0.903,31.087,-1.613,0.53
"1088",1088,1098,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,377.558,"rhizome soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,34.35,NA,15.362,5,NA,NA,5.1,NA,226.5,"rhizome soluble carbohydrates (mmol sucrose/gdw)",1,NA,37.521,NA,16.78,5,0.903,35.971,-3.793,1.119
"1089",1089,1101,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 3","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,45.345,"root soluble carbohydrates (mmol sucrose/gdw)","cellular content","phys","Q",NA,32.39,NA,14.485,5,NA,NA,5.1,NA,31.553,"root soluble carbohydrates (mmol sucrose/gdw)",1,NA,32.378,NA,14.48,5,0.903,32.384,-0.385,0.407
"1090",1090,1104,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, reduced winter metabolism and growth",NA,"Fig 4","winter","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",25,NA,NA,32,0.88,4.49,0.88,4.49,NA,4,NA,NA,100,NA,2.984,"Shoot growth rate (mm/d)","growth rate","biom","dSS",NA,1.69,NA,0.756,5,NA,NA,9,NA,2.524,"Shoot growth rate (mm/d)",2,NA,2.721,NA,1.217,5,0.903,2.265,-0.183,0.402
"1091",1091,1107,"587","Kraemer, GP; Hanisak, MD",2000,"Physiological and growth responses of Thalassia testudinum to environmentally-relevant periods of low irradiance","AQUATIC BOTANY",1,"Turtle grass, during rapid growth period",NA,"Fig 4","spring","1997","Field","coastal",26.5,-82.01,"Caloosahatchee estuary, USA","Thalassia testudinum","seagrass",21,"mesocosm","pots in aquaria",1000,NA,"no","none","shading screen","natural",NA,"PAR",29,NA,NA,27,1.05,6.49,1.05,6.49,NA,4,NA,NA,100,NA,8.184,"Shoot growth rate (mm/d)","growth rate","biom","dSS",NA,1.21,NA,0.542,5,NA,NA,5.1,NA,6.906,"Shoot growth rate (mm/d)",2,NA,3.189,NA,1.426,5,0.903,2.412,-0.479,0.411
"1092",1092,1108,"588","Aguilera, J; Gordillo, FJL; Karsten, U; Figueroa, FL; Niell, FX",2000,"Light quality effect on photosynthesis and efficiency of carbon assimilation in the red alga Porphyra leucosticta","JOURNAL OF PLANT PHYSIOLOGY",1,"red alga Porphyra leucosticta","No light intensity treatment,only qualitative spectral changes",NA,NA,NA,NA,NA,NA,NA,NA,NA,"seagrass",NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1093",1093,1111,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","winter",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",32,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",231,"PAR",14.5,NA,NA,21.5,0.9,8.9,0.9,8.9,NA,4,97.2,NA,100,NA,0.44,"Shoot growth (mg/d)","growth rate","biom","dSS",NA,0.46,NA,0.23,4,64.7,NA,66.6,NA,0.41,"Shoot growth (mg/d)",2,NA,1.3,NA,0.65,4,0.87,0.975,-0.027,0.5
"1094",1094,1113,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","winter",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",32,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",394,"PAR",14.5,NA,NA,17.5,0.5,6.9,0.5,6.9,NA,4,165.5,NA,100,NA,2.37,"Shoot growth (mg/d)","growth rate","biom","dSS",NA,1.42,NA,0.71,4,110.3,NA,66.6,NA,2.39,"Shoot growth (mg/d)",2,NA,0.34,NA,0.17,4,0.87,1.032,0.017,0.5
"1095",1095,1117,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","winter",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",32,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",231,"PAR",14.5,NA,NA,21.5,0.9,8.9,0.9,8.9,NA,4,97.2,NA,100,NA,0.5,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.04,NA,0.02,4,64.7,NA,66.6,NA,0.36,"Shoot mass (g/shoot)",2,NA,0.14,NA,0.07,4,0.87,0.103,-1.182,0.587
"1096",1096,1119,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","winter",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",32,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",394,"PAR",14.5,NA,NA,17.5,0.5,6.9,0.5,6.9,NA,4,165.5,NA,100,NA,1.28,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.94,NA,0.47,4,110.3,NA,66.6,NA,1.33,"Shoot mass (g/shoot)",2,NA,0.22,NA,0.11,4,0.87,0.683,0.064,0.5
"1097",1097,1123,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","winter",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",32,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",231,"PAR",14.5,NA,NA,21.5,0.9,8.9,0.9,8.9,NA,4,97.2,NA,100,NA,0.62,"Rhizome-root mass (g/shoot)","biomass","biom","SS",NA,0.1,NA,0.05,4,64.7,NA,66.6,NA,0.49,"Rhizome-root mass (g/shoot)",2,NA,0.14,NA,0.07,4,0.87,0.122,-0.929,0.554
"1098",1098,1125,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","winter",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",32,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",394,"PAR",14.5,NA,NA,17.5,0.5,6.9,0.5,6.9,NA,4,165.5,NA,100,NA,0.64,"Rhizome-root mass (g/shoot)","biomass","biom","SS",NA,0.42,NA,0.21,4,110.3,NA,66.6,NA,0.67,"Rhizome-root mass (g/shoot)",2,NA,0.16,NA,0.08,4,0.87,0.318,0.082,0.5
"1099",1099,1109,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","summer",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",40,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",430,"PAR",26.5,NA,NA,22.5,0.8,6.3,0.8,6.3,NA,4,179.4,NA,100,NA,0.45,"Shoot growth (mg/d)","growth rate","biom","dSS",NA,0.38,NA,0.19,4,120.4,NA,67.1,NA,0.64,"Shoot growth (mg/d)",2,NA,0.12,NA,0.06,4,0.87,0.282,0.586,0.521
"1100",1100,1110,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","summer",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",40,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",430,"PAR",26.5,NA,NA,22.5,0.8,6.3,0.8,6.3,NA,4,179.4,NA,100,NA,0.45,"Shoot growth (mg/d)","growth rate","biom","dSS",NA,0.38,NA,0.19,4,38.7,NA,21.6,NA,0.16,"Shoot growth (mg/d)",2,NA,0.16,NA,0.08,4,0.87,0.292,-0.865,0.547
"1101",1101,1115,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","summer",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",40,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",430,"PAR",26.5,NA,NA,22.5,0.8,6.3,0.8,6.3,NA,4,179.4,NA,100,NA,0.24,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.12,NA,0.06,4,120.4,NA,67.1,NA,0.33,"Shoot mass (g/shoot)",2,NA,0.08,NA,0.04,4,0.87,0.102,0.767,0.537
"1102",1102,1116,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","summer",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",40,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",430,"PAR",26.5,NA,NA,22.5,0.8,6.3,0.8,6.3,NA,4,179.4,NA,100,NA,0.24,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.12,NA,0.06,4,38.7,NA,21.6,NA,0.07,"Shoot mass (g/shoot)",2,NA,0.14,NA,0.07,4,0.87,0.13,-1.134,0.58
"1103",1103,1121,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","summer",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",40,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",430,"PAR",26.5,NA,NA,22.5,0.8,6.3,0.8,6.3,NA,4,179.4,NA,100,NA,0.33,"Rhizome-root mass (g/shoot)","biomass","biom","SS",NA,0.14,NA,0.07,4,120.4,NA,67.1,NA,0.39,"Rhizome-root mass (g/shoot)",2,NA,0.08,NA,0.04,4,0.87,0.114,0.458,0.513
"1104",1104,1122,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","summer",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",40,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",430,"PAR",26.5,NA,NA,22.5,0.8,6.3,0.8,6.3,NA,4,179.4,NA,100,NA,0.33,"Rhizome-root mass (g/shoot)","biomass","biom","SS",NA,0.14,NA,0.07,4,38.7,NA,21.6,NA,0.16,"Rhizome-root mass (g/shoot)",2,NA,0.14,NA,0.07,4,0.87,0.14,-1.056,0.57
"1105",1105,1112,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","spring",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",41,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",231,"PAR",14.5,NA,NA,21.5,0.9,8.9,0.9,8.9,NA,4,97.2,NA,100,NA,0.44,"Shoot growth (mg/d)","growth rate","biom","dSS",NA,0.46,NA,0.23,4,20.8,NA,21.4,NA,0.07,"Shoot growth (mg/d)",2,NA,0.04,NA,0.02,4,0.87,0.326,-0.985,0.561
"1106",1106,1114,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","spring",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",41,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",394,"PAR",14.5,NA,NA,17.5,0.5,6.9,0.5,6.9,NA,4,165.5,NA,100,NA,2.37,"Shoot growth (mg/d)","growth rate","biom","dSS",NA,1.42,NA,0.71,4,35.5,NA,21.5,NA,1.34,"Shoot growth (mg/d)",2,NA,0.98,NA,0.49,4,0.87,1.22,-0.734,0.534
"1107",1107,1118,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","spring",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",41,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",231,"PAR",14.5,NA,NA,21.5,0.9,8.9,0.9,8.9,NA,4,97.2,NA,100,NA,0.5,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.04,NA,0.02,4,20.8,NA,21.4,NA,0.11,"Shoot mass (g/shoot)",2,NA,0.06,NA,0.03,4,0.87,0.051,-6.651,3.265
"1108",1108,1120,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","spring",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",41,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",394,"PAR",14.5,NA,NA,17.5,0.5,6.9,0.5,6.9,NA,4,165.5,NA,100,NA,1.28,"Shoot mass (g/shoot)","biomass","biom","SS",NA,0.94,NA,0.47,4,35.5,NA,21.5,NA,0.72,"Shoot mass (g/shoot)",2,NA,0.28,NA,0.14,4,0.87,0.694,-0.702,0.531
"1109",1109,1124,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","spring",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",41,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",231,"PAR",14.5,NA,NA,21.5,0.9,8.9,0.9,8.9,NA,4,97.2,NA,100,NA,0.62,"Rhizome-root mass (g/shoot)","biomass","biom","SS",NA,0.1,NA,0.05,4,20.8,NA,21.4,NA,0.22,"Rhizome-root mass (g/shoot)",2,NA,0.04,NA,0.02,4,0.87,0.076,-4.567,1.804
"1110",1110,1126,"595","Moore, KA; Wetzel, RL",2000,"Seasonal variations in eelgrass (Zostera marina L.) responses to nutrient enrichment and reduced light availability in experimental ecosystems","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass",NA,"Table 5","spring",NA,"Field","coastal",37.28,-76.35,"Chesapeake Bay, USA","Zostera marina","seagrass",41,"mesocosm","Aquaria",110,NA,"yes","nutrients","shading screen","natural",394,"PAR",14.5,NA,NA,17.5,0.5,6.9,0.5,6.9,NA,4,165.5,NA,100,NA,0.64,"Rhizome-root mass (g/shoot)","biomass","biom","SS",NA,0.42,NA,0.21,4,35.5,NA,21.5,NA,0.3,"Rhizome-root mass (g/shoot)",2,NA,0.08,NA,0.04,4,0.87,0.302,-0.978,0.56
"1111",1111,1127,"601","Thompson, P",1999,"Response of growth and biochemical composition to variations in daylength, temperature, and irradiance in the marine diatom Thalassiosira pseudonana (Bacillariophyceae)","JOURNAL OF PHYCOLOGY",1,NA,"No duration, STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1112",1112,1128,"613","Popovich, CA; Gayoso, AM",1999,"Effect of irradiance and temperature on the growth rate of Thalassiosira curviseriata Takano (Bacillariophyceae), a bloom diatom in Bahia Blanca estuary (Argentina)","JOURNAL OF PLANKTON RESEARCH",1,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1113",1113,1129,"616","Janssen, M; Kuijpers, TC; Veldhoen, B; Ternbach, MB; Tramper, J; Mur, LR; Wijffels, RH",1999,"Specific growth rate of Chlamydomonas reinhardtii and Chlorella sorokiniana under medium duration light dark cycles: 13-87 s","JOURNAL OF BIOTECHNOLOGY",NA,NA,"Measures on an hourly basis, with very short light cycle duration",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1114",1114,1130,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",3,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,59.914,"Total Biomass (g/m2)",2,NA,8.475,NA,4.893,3,0.8,10.084,0.945,0.741
"1115",1115,1138,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",3,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,17.022,"leaf sugar concentration (mg/g)",1,NA,27.482,NA,15.867,3,0.8,19.548,-0.527,0.69
"1116",1116,1146,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",3,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,90.914,"root starch concentration (mg/g)",1,NA,6.793,NA,3.922,3,0.8,6.792,0.513,0.689
"1117",1117,1153,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",3,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.75,"Fv/Fm",1,NA,0.026,NA,0.015,3,0.8,0.035,-0.138,0.668
"1118",1118,1131,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",6,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,53.124,"Total Biomass (g/m2)",2,NA,18.334,NA,10.585,3,0.8,15.292,0.268,0.673
"1119",1119,1139,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",6,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,15.858,"leaf sugar concentration (mg/g)",1,NA,29.182,NA,16.848,3,0.8,20.743,-0.541,0.691
"1120",1120,1147,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",6,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,94.292,"root starch concentration (mg/g)",1,NA,13.339,NA,7.701,3,0.8,10.584,0.585,0.695
"1121",1121,1154,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",6,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.757,"Fv/Fm",1,NA,0.026,NA,0.015,3,0.8,0.035,0.023,0.667
"1122",1122,1132,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",9,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,44.736,"Total Biomass (g/m2)",2,NA,6.573,NA,3.795,3,0.8,9.348,-0.279,0.673
"1123",1123,1140,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",9,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,17.664,"leaf sugar concentration (mg/g)",1,NA,30.881,NA,17.829,3,0.8,21.939,-0.446,0.683
"1124",1124,1148,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",9,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,82.544,"root starch concentration (mg/g)",1,NA,13.098,NA,7.562,3,0.8,10.433,-0.308,0.675
"1125",1125,1155,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",9,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.764,"Fv/Fm",1,NA,0.028,NA,0.016,3,0.8,0.035,0.181,0.669
"1126",1126,1133,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",12,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,34.151,"Total Biomass (g/m2)",2,NA,6.92,NA,3.995,3,0.8,9.472,-1.17,0.781
"1127",1127,1141,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",12,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,15.264,"leaf sugar concentration (mg/g)",1,NA,30.437,NA,17.573,3,0.8,21.627,-0.541,0.691
"1128",1128,1149,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",12,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,101.189,"root starch concentration (mg/g)",1,NA,14.069,NA,8.123,3,0.8,11.047,1.06,0.76
"1129",1129,1156,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",12,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.701,"Fv/Fm",1,NA,0.04,NA,0.023,3,0.8,0.041,-1.081,0.764
"1130",1130,1134,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",15,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,22.568,"Total Biomass (g/m2)",2,NA,7.609,NA,4.393,3,0.8,9.733,-2.09,1.031
"1131",1131,1142,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",15,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,16.245,"leaf sugar concentration (mg/g)",1,NA,30.566,NA,17.647,3,0.8,21.717,-0.503,0.688
"1132",1132,1150,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",15,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,101.63,"root starch concentration (mg/g)",1,NA,9.216,NA,5.321,3,0.8,8.095,1.49,0.852
"1133",1133,1157,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",15,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.753,"Fv/Fm",1,NA,0.024,NA,0.014,3,0.8,0.034,-0.071,0.667
"1134",1134,1135,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",18,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,21.17,"Total Biomass (g/m2)",2,NA,5.534,NA,3.195,3,0.8,9.005,-2.384,1.14
"1135",1135,1143,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",18,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,17.143,"leaf sugar concentration (mg/g)",1,NA,33.692,NA,19.452,3,0.8,23.918,-0.427,0.682
"1136",1136,1151,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",18,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,93.103,"root starch concentration (mg/g)",1,NA,17.951,NA,10.364,3,0.8,13.571,0.386,0.679
"1137",1137,1158,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",18,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.732,"Fv/Fm",1,NA,0.024,NA,0.014,3,0.8,0.034,-0.564,0.693
"1138",1138,1136,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",21,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,9.586,"Total Biomass (g/m2)",2,NA,5.536,NA,3.196,3,0.8,9.005,-3.413,1.637
"1139",1139,1144,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",21,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,15.98,"leaf sugar concentration (mg/g)",1,NA,29.821,NA,17.217,3,0.8,21.193,-0.525,0.69
"1140",1140,1152,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",21,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,86.555,"root starch concentration (mg/g)","cellular content","phys","Q",NA,6.79,NA,3.92,3,NA,NA,NA,NA,95.502,"root starch concentration (mg/g)",1,NA,9.703,NA,5.602,3,0.8,8.375,0.855,0.728
"1141",1141,1159,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",21,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.704,"Fv/Fm",1,NA,0.071,NA,0.041,3,0.8,0.058,-0.715,0.709
"1142",1142,1137,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 2a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",24,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,48,"Total Biomass (g/m2)","biomass","biom","SS",NA,11.47,NA,6.62,3,NA,NA,NA,NA,7.989,"Total Biomass (g/m2)",2,NA,5.361,NA,3.095,3,0.8,8.952,-3.575,1.732
"1143",1143,1145,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",24,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,29.897,"leaf sugar concentration (mg/g)","cellular content","phys","Q",NA,3,NA,1.73,3,NA,NA,NA,NA,14.733,"leaf sugar concentration (mg/g)",1,NA,21.519,NA,12.424,3,0.8,15.363,-0.79,0.719
"1144",1144,1160,"620","Longstaff, BJ; Loneragan, NR; O'Donohue, MJ; Dennison, WC",1999,"Effects of light deprivation on the survival and recovery of the seagrass Halophila ovalis (RBr) Hook","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, 1 week acclimation at 7% surface irradiance, 7% used as CTRL, 0% as TRT. Initial CTRL value assumed as last day value too",NA,"Fig 3a","spring","1995","Lab","coastal",-27.49,153.4,"One Mile Harbour, Australia","Halophila ovalis","seagrass",24,"mesocosm","outdoor fibreglass aquaria",200,NA,"no","none","shading screen","0",NA,NA,22,NA,NA,35.5,NA,NA,NA,NA,NA,0,NA,NA,100,NA,0.756,"Fv/Fm","quantum yield","phys","dQ",NA,0.042,NA,0.024,3,NA,NA,NA,NA,0.735,"Fv/Fm",1,NA,0.033,NA,0.019,3,0.8,0.037,-0.448,0.683
"1145",1145,1173,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Fig 4",NA,NA,"Lab","culture",NA,NA,NA,"Total phytoplankton","phytoplankton",8,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,10.378,"Chl a (µg/L)","biomass","biom","SS",NA,0.689,NA,0.487,2,35,NA,17.5,NA,19.622,"Chl a (µg/L)",2,NA,1.261,NA,0.892,2,0.571,1.016,5.198,4.377
"1146",1146,1174,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Fig 4",NA,NA,"Lab","culture",NA,NA,NA,"Total phytoplankton","phytoplankton",8,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,28.297,"Chl a (µg/L)","biomass","biom","SS",NA,0.46,NA,0.325,2,35,NA,17.5,NA,22.216,"Chl a (µg/L)",2,NA,1.491,NA,1.054,2,0.571,1.103,-3.15,2.241
"1147",1147,1161,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pacifica","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,1.5,5,1.5,5,79.1,5,200,NA,100,NA,1435,"cell /mL","abundance","biom","SS",NA,99,NA,70,2,35,NA,17.5,NA,260,"cell /mL",2,NA,6,NA,4,2,0.571,70.114,-9.576,12.463
"1148",1148,1162,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Rhizosolenia setigera","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,1.5,5,1.5,5,79.1,5,200,NA,100,NA,100,"cell /mL","abundance","biom","SS",NA,7,NA,5,2,35,NA,17.5,NA,44,"cell /mL",2,NA,1.4,NA,1,2,0.571,5.099,-6.276,5.923
"1149",1149,1163,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Chaetoceros sp.","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,1.5,5,1.5,5,79.1,5,200,NA,100,NA,210,"cell /mL","abundance","biom","SS",NA,85,NA,60,2,35,NA,17.5,NA,340,"cell /mL",2,NA,28,NA,20,2,0.571,63.246,1.175,1.172
"1150",1150,1164,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Pseudo-Nitzschia multiseries","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,1.5,5,1.5,5,79.1,5,200,NA,100,NA,730,"cell /mL","abundance","biom","SS",NA,113,NA,80,2,35,NA,17.5,NA,1420,"cell /mL",2,NA,85,NA,60,2,0.571,100,3.943,2.943
"1151",1151,1165,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema costatum","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,1.5,5,1.5,5,79.1,5,200,NA,100,NA,37900,"cell /mL","abundance","biom","SS",NA,1838,NA,1300,2,35,NA,17.5,NA,17500,"cell /mL",2,NA,1301,NA,920,2,0.571,1592.608,-7.32,7.697
"1152",1152,1166,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeocystis pouchetii","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,1.5,5,1.5,5,79.1,5,200,NA,100,NA,26600,"cell /mL","abundance","biom","SS",NA,3677,NA,2600,2,35,NA,17.5,NA,26700,"cell /mL",2,NA,57,NA,40,2,0.571,2600.308,0.022,1
"1153",1153,1167,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pacifica","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,1800,"cell /mL","abundance","biom","SS",NA,14,NA,10,2,35,NA,17.5,NA,220,"cell /mL",2,NA,28,NA,20,2,0.571,22.361,-40.377,204.788
"1154",1154,1168,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Rhizosolenia setigera","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,30,"cell /mL","abundance","biom","SS",NA,14,NA,10,2,35,NA,17.5,NA,21,"cell /mL",2,NA,1.4,NA,1,2,0.571,10.05,-0.512,1.033
"1155",1155,1169,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Chaetoceros sp.","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,120,"cell /mL","abundance","biom","SS",NA,99,NA,70,2,35,NA,17.5,NA,1480,"cell /mL",2,NA,240,NA,170,2,0.571,183.848,4.227,3.234
"1156",1156,1170,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Pseudo-Nitzschia multiseries","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,300,"cell /mL","abundance","biom","SS",NA,57,NA,40,2,35,NA,17.5,NA,1000,"cell /mL",2,NA,99,NA,70,2,0.571,80.623,4.961,4.077
"1157",1157,1171,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema costatum","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,29600,"cell /mL","abundance","biom","SS",NA,2404,NA,1700,2,35,NA,17.5,NA,16400,"cell /mL",2,NA,2546,NA,1800,2,0.571,2475.884,-3.047,2.16
"1158",1158,1172,"643","Hegarty, SG; Villareal, TA",1998,"Effects of light level and N : P supply ratio on the competition between Phaeocystis cf. pouchetii (Hariot) Lagerheim (Prymnesiophyceae) and five diatom species","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"Different duration for HL and LL, experiments run at different times",NA,"Table 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeocystis pouchetii","phytoplankton",15,"microcosm","Polycarbonate bottles",1,NA,"no","nutrients","shading screen","12",NA,NA,10.8,NA,NA,NA,0.4,23.3,0.4,23.3,78.2,5,200,NA,100,NA,114300,"cell /mL","abundance","biom","SS",NA,10041,NA,7100,2,35,NA,17.5,NA,10200,"cell /mL",2,NA,1499,NA,1060,2,0.571,7178.691,-8.286,9.583
"1159",1159,1175,"652","Livingston, RJ; McGlynn, SE; Niu, XF",1998,"Factors controlling seagrass growth in a gulf coastal system: Water and sediment quality and light","AQUATIC BOTANY",1,"seagrass","No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1160",1160,1176,"662","Nielsen, MV",1997,"Growth, dark respiration and photosynthetic parameters of the coccolithophorid Emiliania huxleyi (Prymnesiophyceae) acclimated to different day length-irradiance combinations","JOURNAL OF PHYCOLOGY",1,NA,"No experiment duration given, nor the amount or replicates","Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliana huxleyi","phytoplankton",NA,"microcosm","glass flask",0.8,NA,"no","interval","shading screen",NA,NA,NA,15,NA,NA,34,NA,NA,NA,NA,NA,0,800,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,2,200,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,2,NA,NA,NA,NA
"1161",1161,1179,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 3","spring","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",36,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,6.82,"Blade width (mm)","biomass","biom","SS",NA,0.26,NA,0.15,3,104,NA,34.9,NA,6.61,"Blade width (mm)",2,NA,0.346,NA,0.2,3,0.8,0.306,-0.549,0.692
"1162",1162,1180,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 3","spring","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",36,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,6.82,"Blade width (mm)","biomass","biom","SS",NA,0.26,NA,0.15,3,55,NA,18.5,NA,5.96,"Blade width (mm)",2,NA,0.242,NA,0.14,3,0.8,0.251,-2.738,1.291
"1163",1163,1185,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5","spring","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",36,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,4.04,"Leaf production rate (mg shoot /d)","growth rate","biom","dSS",NA,0.554,NA,0.32,3,104,NA,34.9,NA,3.2,"Leaf production rate (mg shoot /d)",2,NA,0.693,NA,0.4,3,0.8,0.627,-1.071,0.762
"1164",1164,1186,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5","spring","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",36,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,4.04,"Leaf production rate (mg shoot /d)","growth rate","biom","dSS",NA,0.554,NA,0.32,3,55,NA,18.5,NA,1.59,"Leaf production rate (mg shoot /d)",2,NA,0.329,NA,0.19,3,0.8,0.456,-4.3,2.208
"1165",1165,1189,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5a","spring","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",36,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,2.48,"Areal leaf production rate (g /m2 /d)","area-specific production","biom","dSS",NA,0.329,NA,0.19,3,104,NA,34.9,NA,1.94,"Areal leaf production rate (g /m2 /d)",2,NA,0.416,NA,0.24,3,0.8,0.375,-1.152,0.777
"1166",1166,1190,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5a","spring","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",36,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,2.48,"Areal leaf production rate (g /m2 /d)","area-specific production","biom","dSS",NA,0.329,NA,0.19,3,55,NA,18.5,NA,0.97,"Areal leaf production rate (g /m2 /d)",2,NA,0.208,NA,0.12,3,0.8,0.275,-4.389,2.272
"1167",1167,1177,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 2","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,785,"shoots/m2","abundance","biom","SS",NA,139,NA,80,3,104,NA,34.9,NA,296,"shoots/m2",2,NA,69,NA,40,3,0.8,109.545,-3.571,1.729
"1168",1168,1178,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 2","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,785,"shoot density/m3","abundance","biom","SS",NA,139,NA,80,3,55,NA,18.5,NA,168,"shoot density/m3",2,NA,52,NA,30,3,0.8,104.642,-4.717,2.521
"1169",1169,1193,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,971.2,"Total Biomass (g/m2)","biomass","biom","SS",NA,192.604,NA,111.2,3,104,NA,34.9,NA,421.4,"Total Biomass (g/m2)",2,NA,69.975,NA,40.4,3,0.8,144.901,-3.035,1.434
"1170",1170,1194,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,971.2,"Total Biomass (g/m2)","biomass","biom","SS",NA,192.604,NA,111.2,3,55,NA,18.5,NA,307.9,"Total Biomass (g/m2)",2,NA,96.995,NA,56,3,0.8,152.487,-3.48,1.676
"1171",1171,1199,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,445.3,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,118.126,NA,68.2,3,104,NA,34.9,NA,122.1,"Leaf Biomass (g dw/m2)",2,NA,42.262,NA,24.4,3,0.8,88.712,-2.915,1.375
"1172",1172,1200,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,445.3,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,118.126,NA,68.2,3,55,NA,18.5,NA,30.1,"Leaf Biomass (g dw/m2)",2,NA,13.856,NA,8,3,0.8,84.1,-3.95,1.967
"1173",1173,1205,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,200.7,"Rhizome Biomass (g dw/m2)","biomass","biom","SS",NA,66.857,NA,38.6,3,104,NA,34.9,NA,114.6,"Rhizome Biomass (g dw/m2)",2,NA,0,NA,0,15,0.953,23.564,-3.481,0.734
"1174",1174,1206,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,200.7,"Rhizome Biomass (g dw/m2)","biomass","biom","SS",NA,66.857,NA,38.6,3,55,NA,18.5,NA,129.6,"Rhizome Biomass (g dw/m2)",2,NA,19.919,NA,11.5,3,0.8,49.329,-1.153,0.777
"1175",1175,1211,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,129.6,"Root Biomass (C g/m2)","biomass","biom","SS",NA,19.053,NA,11,3,104,NA,34.9,NA,73.9,"Root Biomass (C g/m2)",2,NA,14.722,NA,8.5,3,0.8,17.026,-2.617,1.237
"1176",1176,1212,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",116,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,129.6,"Root Biomass (C g/m2)","biomass","biom","SS",NA,19.053,NA,11,3,55,NA,18.5,NA,44.6,"Root Biomass (C g/m2)",2,NA,24.768,NA,14.3,3,0.8,22.096,-3.077,1.456
"1177",1177,1181,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",128,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,6.95,"Blade width (mm)","biomass","biom","SS",NA,0.433,NA,0.25,3,104,NA,34.9,NA,5.89,"Blade width (mm)",2,NA,0.173,NA,0.1,3,0.8,0.33,-2.571,1.218
"1178",1178,1182,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 3","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",128,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,6.95,"Blade width (mm)","biomass","biom","SS",NA,0.433,NA,0.25,3,55,NA,18.5,NA,4.76,"Blade width (mm)",2,NA,0.225,NA,0.13,3,0.8,0.345,-5.077,2.814
"1179",1179,1187,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",128,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,3.3,"Leaf production rate (mg shoot /d)","growth rate","biom","dSS",NA,0.71,NA,0.41,3,104,NA,34.9,NA,2.08,"Leaf production rate (mg shoot /d)",2,NA,0.329,NA,0.19,3,0.8,0.553,-1.764,0.926
"1180",1180,1188,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",128,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,3.3,"Leaf production rate (mg shoot /d)","growth rate","biom","dSS",NA,0.71,NA,0.41,3,55,NA,18.5,NA,0.99,"Leaf production rate (mg shoot /d)",2,NA,0.225,NA,0.13,3,0.8,0.527,-3.508,1.692
"1181",1181,1191,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5b","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",128,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,3.06,"Areal leaf production rate (g /m2 /d)","area-specific production","biom","dSS",NA,0.675,NA,0.39,3,104,NA,34.9,NA,0.76,"Areal leaf production rate (g /m2 /d)",2,NA,0.087,NA,0.05,3,0.8,0.482,-3.821,1.883
"1182",1182,1192,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 5b","fall","1993","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",128,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,3.06,"Areal leaf production rate (g /m2 /d)","area-specific production","biom","dSS",NA,0.675,NA,0.39,3,55,NA,18.5,NA,0.23,"Areal leaf production rate (g /m2 /d)",2,NA,0.087,NA,0.05,3,0.8,0.482,-4.701,2.509
"1183",1183,1183,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 4","spring","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,4.72,"Biomass (mg Chl a /gdw)","biomass","biom","SS",NA,0.433,NA,0.25,3,104,NA,34.9,NA,5.42,"Biomass (mg Chl a /gdw)",2,NA,0.416,NA,0.24,3,0.8,0.424,1.319,0.812
"1184",1184,1195,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","spring","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,367.5,"Total Biomass (g/m2)","biomass","biom","SS",NA,59.583,NA,34.4,3,104,NA,34.9,NA,73.8,"Total Biomass (g/m2)",2,NA,32.909,NA,19,3,0.8,48.13,-4.882,2.653
"1185",1185,1196,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","spring","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,367.5,"Total Biomass (g/m2)","biomass","biom","SS",NA,59.583,NA,34.4,3,55,NA,18.5,NA,0,"Total Biomass (g/m2)",2,NA,0,NA,0,3,0.8,42.131,-6.978,4.725
"1186",1186,1201,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,63.4,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,18.187,NA,10.5,3,104,NA,34.9,NA,7.8,"Leaf Biomass (g dw/m2)",2,NA,4.33,NA,2.5,3,0.8,13.219,-3.365,1.61
"1187",1187,1202,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,63.4,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,18.187,NA,10.5,3,55,NA,18.5,NA,0,"Leaf Biomass (g dw/m2)",2,NA,0,NA,0,3,0.8,12.86,-3.944,1.963
"1188",1188,1207,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","fall","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,185.6,"Rhizome Biomass (g dw/m2)","biomass","biom","SS",NA,20.958,NA,12.1,3,104,NA,34.9,NA,36.3,"Rhizome Biomass (g dw/m2)",2,NA,16.628,NA,9.6,3,0.8,18.917,-6.314,3.989
"1189",1189,1208,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","spring","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,185.6,"Rhizome Biomass (g dw/m2)","biomass","biom","SS",NA,20.958,NA,12.1,3,55,NA,18.5,NA,0,"Rhizome Biomass (g dw/m2)",2,NA,0,NA,0,3,0.8,14.819,-10.019,9.032
"1190",1190,1213,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","spring","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,31.3,"Root Biomass (C g/m2)","biomass","biom","SS",NA,8.833,NA,5.1,3,104,NA,34.9,NA,3.7,"Root Biomass (C g/m2)",2,NA,1.905,NA,1.1,3,0.8,6.39,-3.455,1.662
"1191",1191,1214,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","spring","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",345,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,31.3,"Root Biomass (C g/m2)","biomass","biom","SS",NA,8.833,NA,5.1,3,55,NA,18.5,NA,0,"Root Biomass (C g/m2)",2,NA,0,NA,0,3,0.8,6.246,-4.009,2.006
"1192",1192,1184,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance.",NA,"Fig 4","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,5.2,"Biomass (mg Chl a /gdw)","biomass","biom","SS",NA,0.45,NA,0.26,3,104,NA,34.9,NA,5.63,"Biomass (mg Chl a /gdw)",2,NA,0.572,NA,0.33,3,0.8,0.515,0.669,0.704
"1193",1193,1197,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,561.5,"Total Biomass (g/m2)","biomass","biom","SS",NA,148.09,NA,85.5,3,104,NA,34.9,NA,21.1,"Total Biomass (g/m2)",2,NA,20.438,NA,11.8,3,0.8,105.708,-4.09,2.061
"1194",1194,1198,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,561.5,"Total Biomass (g/m2)","biomass","biom","SS",NA,148.09,NA,85.5,3,55,NA,18.5,NA,0,"Total Biomass (g/m2)",2,NA,0,NA,0,3,0.8,104.716,-4.29,2.2
"1195",1195,1203,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,181.2,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,44.341,NA,25.6,3,104,NA,34.9,NA,0.6,"Leaf Biomass (g dw/m2)",2,NA,0.693,NA,0.4,3,0.8,31.357,-4.608,2.436
"1196",1196,1204,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,181.2,"Leaf Biomass (g dw/m2)","biomass","biom","SS",NA,44.341,NA,25.6,3,55,NA,18.5,NA,0,"Leaf Biomass (g dw/m2)",2,NA,0,NA,0,3,0.8,31.353,-4.623,2.448
"1197",1197,1209,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,216.8,"Rhizome Biomass (g dw/m2)","biomass","biom","SS",NA,50.922,NA,29.4,3,104,NA,34.9,NA,14.3,"Rhizome Biomass (g dw/m2)",2,NA,17.494,NA,10.1,3,0.8,38.073,-4.255,2.175
"1198",1198,1210,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,216.8,"Rhizome Biomass (g dw/m2)","biomass","biom","SS",NA,50.922,NA,29.4,3,55,NA,18.5,NA,0,"Rhizome Biomass (g dw/m2)",2,NA,0,NA,0,3,0.8,36.007,-4.817,2.6
"1199",1199,1215,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,40.2,"Root Biomass (C g/m2)","biomass","biom","SS",NA,8.833,NA,5.1,3,104,NA,34.9,NA,0.2,"Root Biomass (C g/m2)",2,NA,0.346,NA,0.2,3,0.8,6.251,-5.119,2.851
"1200",1200,1216,"675","Lee, KS; Dunton, KH",1997,"Effects of in situ light reduction on the maintenance, growth and partitioning of carbon resources in Thalassia testudinum Banks ex Konig","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiance measured at canopy level. Percentages of surface irradiance. Not all values available for 5% trt",NA,"Table 3","summer","1994","Field","coastal",27.82,97.12,"Corpus Christi Bay, USA","Thalassia testudinum","seagrass",457,"field plot","no container",NA,2.25,"unknown","none","shading screen","natural",NA,"PAR",23.5,NA,NA,29.5,NA,NA,NA,NA,NA,0,298,NA,100,NA,40.2,"Root Biomass (C g/m2)","biomass","biom","SS",NA,8.833,NA,5.1,3,55,NA,18.5,NA,0,"Root Biomass (C g/m2)",2,NA,0,NA,0,3,0.8,6.246,-5.149,2.876
"1201",1201,1217,"689","Shiah, FK; Gong, GC; Liu, KK",1996,"Light effects on phytoplankton photosynthetic performance in the southern East China Sea north of Taiwan","BOTANICAL BULLETIN OF ACADEMIA SINICA",1,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1202",1202,1218,"694","Barranguet, C; Cervetto, G; Fontaine, MF",1996,"Microphytobenthos production in a Mediterranean mussel farm: The influence of incident light","COMPTES RENDUS DE L ACADEMIE DES SCIENCES SERIE III-SCIENCES DE LA VIE-LIFE SCIENCES",1,"MPB","Only a 4h incubation, no STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1203",1203,1219,"699","FITZPATRICK, J; KIRKMAN, H",1995,"EFFECTS OF PROLONGED SHADING STRESS ON GROWTH AND SURVIVAL OF SEAGRASS POSIDONIA-AUSTRALIS IN JERVIS-BAY, NEW-SOUTH-WALES, AUSTRALIA","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass posidonia",NA,"Fig 7","spring","1990","Field","coastal",-35.12,150.7,"Jervis Bay, Australia","Posidonia australis","seagrass",91,"field plot","no container",NA,0.0625,"unknown","none","shading screen","natural",NA,"PAR",24,NA,NA,NA,NA,NA,NA,NA,NA,0,650,NA,100,NA,20.568,"number of shoots/0.0625m2","abundance","biom","SS",NA,3.093,NA,0.978,10,20,NA,3.1,NA,11.109,"number of shoots/0.0625m2",2,NA,4.689,NA,1.483,10,0.958,3.972,-2.281,0.33
"1204",1204,1221,"699","FITZPATRICK, J; KIRKMAN, H",1995,"EFFECTS OF PROLONGED SHADING STRESS ON GROWTH AND SURVIVAL OF SEAGRASS POSIDONIA-AUSTRALIS IN JERVIS-BAY, NEW-SOUTH-WALES, AUSTRALIA","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass posidonia",NA,"Fig 8","spring","1990","Field","coastal",-35.12,150.7,"Jervis Bay, Australia","Posidonia australis","seagrass",91,"field plot","no container",NA,0.0625,"unknown","none","shading screen","natural",NA,"PAR",24,NA,NA,NA,NA,NA,NA,NA,NA,0,650,NA,100,NA,8.717,"growth rate (mgdw/shoot/d)","growth rate","biom","dSS",NA,1.018,NA,0.322,10,20,NA,3.1,NA,2.175,"growth rate (mgdw/shoot/d)",2,NA,1.468,NA,0.464,10,0.958,1.263,-4.96,0.815
"1205",1205,1220,"699","FITZPATRICK, J; KIRKMAN, H",1995,"EFFECTS OF PROLONGED SHADING STRESS ON GROWTH AND SURVIVAL OF SEAGRASS POSIDONIA-AUSTRALIS IN JERVIS-BAY, NEW-SOUTH-WALES, AUSTRALIA","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass posidonia",NA,"Fig 7","fall","1991","Field","coastal",-35.12,150.7,"Jervis Bay, Australia","Posidonia australis","seagrass",95,"field plot","no container",NA,0.0625,"unknown","none","shading screen","natural",NA,"PAR",15,NA,NA,NA,NA,NA,NA,NA,NA,0,650,NA,100,NA,19.845,"number of shoots/0.0625m2","abundance","biom","SS",NA,2.629,NA,0.679,15,20,NA,3.1,NA,15.849,"number of shoots/0.0625m2",2,NA,4.846,NA,1.251,15,0.973,3.898,-0.997,0.15
"1206",1206,1222,"699","FITZPATRICK, J; KIRKMAN, H",1995,"EFFECTS OF PROLONGED SHADING STRESS ON GROWTH AND SURVIVAL OF SEAGRASS POSIDONIA-AUSTRALIS IN JERVIS-BAY, NEW-SOUTH-WALES, AUSTRALIA","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass posidonia",NA,"Fig 8","fall","1991","Field","coastal",-35.12,150.7,"Jervis Bay, Australia","Posidonia australis","seagrass",95,"field plot","no container",NA,0.0625,"unknown","none","shading screen","natural",NA,"PAR",15,NA,NA,NA,NA,NA,NA,NA,NA,0,650,NA,100,NA,3.679,"growth rate (mgdw/shoot/d)","growth rate","biom","dSS",NA,0.799,NA,0.206,15,20,NA,3.1,NA,1.793,"growth rate (mgdw/shoot/d)",2,NA,0.372,NA,0.096,15,0.973,0.623,-2.944,0.278
"1207",1207,1223,"716","GOODMAN, JL; MOORE, KA; DENNISON, WC",1995,"PHOTOSYNTHETIC RESPONSES OF EELGRASS (ZOSTERA-MARINA L) TO LIGHT AND SEDIMENT SULFIDE IN A SHALLOW BARRIER-ISLAND LAGOON","AQUATIC BOTANY",1,"eelgrass","no usable measures given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1208",1208,1224,"718","LATASA, M",1995,"PIGMENT COMPOSITION OF HETEROCAPSA SP AND THALASSIOSIRA-WEISSFLOGII GROWING IN BATCH CULTURES UNDER DIFFERENT IRRADIANCES","SCIENTIA MARINA",1,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1209",1209,1225,"719","VANLENT, F; VERSCHUURE, JM; VANVEGHEL, MLJ",1995,"COMPARATIVE-STUDY ON POPULATIONS OF ZOSTERA-MARINA L (EELGRASS) - IN-SITU NITROGEN ENRICHMENT AND LIGHT MANIPULATION","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass. No exact duration given (2 months)",NA,"Table 3","summer","1989","Field","coastal",51.55,3.85,"Veerse Meer, Netherlands","Zostera marina","seagrass",60,"field plot","no container",NA,0.04,"unknown","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,388,NA,100,NA,85,"number of shoots","abundance","biom","SS",NA,8.485,NA,6,2,225,NA,58,NA,36,"number of shoots",2,NA,15.556,NA,11,2,0.571,12.53,-2.235,1.624
"1210",1210,1226,"719","VANLENT, F; VERSCHUURE, JM; VANVEGHEL, MLJ",1995,"COMPARATIVE-STUDY ON POPULATIONS OF ZOSTERA-MARINA L (EELGRASS) - IN-SITU NITROGEN ENRICHMENT AND LIGHT MANIPULATION","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass. No exact duration given (2 months)",NA,"Table 3","summer","1989","Field","coastal",51.55,3.85,"Veerse Meer, Netherlands","Zostera marina","seagrass",60,"field plot","no container",NA,0.04,"unknown","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,388,NA,100,NA,14.87,"aboveground Biomass (gdw)","biomass","biom","SS",NA,3.833,NA,2.71,2,225,NA,58,NA,7.77,"aboveground Biomass (gdw)",2,NA,2.432,NA,1.72,2,0.571,3.21,-1.264,1.2
"1211",1211,1227,"719","VANLENT, F; VERSCHUURE, JM; VANVEGHEL, MLJ",1995,"COMPARATIVE-STUDY ON POPULATIONS OF ZOSTERA-MARINA L (EELGRASS) - IN-SITU NITROGEN ENRICHMENT AND LIGHT MANIPULATION","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass. No exact duration given (2 months)",NA,"Table 3","summer","1989","Field","coastal",51.55,3.85,"Veerse Meer, Netherlands","Zostera marina","seagrass",60,"field plot","no container",NA,0.04,"unknown","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,388,NA,100,NA,1.6,"belowground Biomass (gdw)","biomass","biom","SS",NA,0.085,NA,0.06,2,225,NA,58,NA,0.82,"belowground Biomass (gdw)",2,NA,0.438,NA,0.31,2,0.571,0.316,-1.412,1.249
"1212",1212,1228,"719","VANLENT, F; VERSCHUURE, JM; VANVEGHEL, MLJ",1995,"COMPARATIVE-STUDY ON POPULATIONS OF ZOSTERA-MARINA L (EELGRASS) - IN-SITU NITROGEN ENRICHMENT AND LIGHT MANIPULATION","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass. No exact duration given (2 months)",NA,"Table 3","summer","1989","Field","coastal",51.55,3.85,"Veerse Meer, Netherlands","Zostera marina","seagrass",60,"field plot","no container",NA,0.04,"unknown","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,388,NA,100,NA,16.48,"total Biomass (gdw)","biomass","biom","SS",NA,3.903,NA,2.76,2,225,NA,58,NA,8.59,"total Biomass (gdw)",2,NA,2.871,NA,2.03,2,0.571,3.426,-1.316,1.216
"1213",1213,1229,"719","VANLENT, F; VERSCHUURE, JM; VANVEGHEL, MLJ",1995,"COMPARATIVE-STUDY ON POPULATIONS OF ZOSTERA-MARINA L (EELGRASS) - IN-SITU NITROGEN ENRICHMENT AND LIGHT MANIPULATION","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"eelgrass. No exact duration given (2 months)",NA,"Table 3","summer","1989","Field","coastal",51.55,3.85,"Veerse Meer, Netherlands","Zostera marina","seagrass",60,"field plot","no container",NA,0.04,"unknown","none","shading screen","natural",NA,"PAR",NA,NA,NA,NA,NA,NA,NA,NA,NA,0,388,NA,100,NA,0.033,"growth rate (g/gdw/d)","growth rate","biom","dSS",NA,0.008,NA,0.001,58,225,NA,58,NA,0.033,"growth rate (g/gdw/d)",2,NA,0.008,NA,0.001,57,0.993,0.008,0,0.035
"1214",1214,1230,"723","ANDERSSON, A; HAECKY, P; HAGSTROM, A",1994,"EFFECT OF TEMPERATURE AND LIGHT ON THE GROWTH OF MICRO-PLANKTON NANO-PLANKTON AND PICO-PLANKTON - IMPACT ON ALGAL SUCCESSION","MARINE BIOLOGY",1,"No exact experiment duration given (3-4 weeks)",NA,"Table 2","annual","1989-1990","Lab","coastal",63.52,19.8,"Baltic Sea, Sweden","Total phytoplankton (2-200um)","phytoplankton",24,"microcosm","bottle",0.25,NA,"no","temperature","reduced light","12",NA,"PAR",1,NA,NA,NA,3.228888889,15.421536,3.228888889,15.421536,NA,4,110,NA,100,62,70,"Cell volume (pg C/cell)","cellular content","phys","Q",14.142,9.899,10,7,2,45,NA,40.9,71,73,"Cell volume (pg C/cell)",1,33.941,24.042,24,17,2,0.571,18.385,0.093,1.001
"1215",1215,1231,"723","ANDERSSON, A; HAECKY, P; HAGSTROM, A",1994,"EFFECT OF TEMPERATURE AND LIGHT ON THE GROWTH OF MICRO-PLANKTON NANO-PLANKTON AND PICO-PLANKTON - IMPACT ON ALGAL SUCCESSION","MARINE BIOLOGY",1,"No exact experiment duration given (3-4 weeks)",NA,"Table 2","annual","1989-1990","Lab","coastal",63.52,19.8,"Baltic Sea, Sweden","Total phytoplankton (2-200um)","phytoplankton",24,"microcosm","bottle",0.25,NA,"no","temperature","reduced light","12",NA,"PAR",5,NA,NA,NA,3.228888889,15.421536,3.228888889,15.421536,NA,4,110,NA,100,62,77,"Cell volume (pg C/cell)","cellular content","phys","Q",14.142,16.971,10,12,2,45,NA,40.9,71,59,"Cell volume (pg C/cell)",1,33.941,19.799,24,14,2,0.571,18.439,-0.558,1.039
"1216",1216,1232,"723","ANDERSSON, A; HAECKY, P; HAGSTROM, A",1994,"EFFECT OF TEMPERATURE AND LIGHT ON THE GROWTH OF MICRO-PLANKTON NANO-PLANKTON AND PICO-PLANKTON - IMPACT ON ALGAL SUCCESSION","MARINE BIOLOGY",1,"No exact experiment duration given (3-4 weeks)",NA,"Table 2","annual","1989-1990","Lab","coastal",63.52,19.8,"Baltic Sea, Sweden","Total phytoplankton (2-200um)","phytoplankton",24,"microcosm","bottle",0.25,NA,"no","temperature","reduced light","12",NA,"PAR",10,NA,NA,NA,3.228888889,15.421536,3.228888889,15.421536,NA,4,110,NA,100,62,27,"Cell volume (pg C/cell)","cellular content","phys","Q",14.142,7.071,10,5,2,45,NA,40.9,71,27,"Cell volume (pg C/cell)",1,33.941,5.657,24,4,2,0.571,6.403,0,1
"1217",1217,1233,"723","ANDERSSON, A; HAECKY, P; HAGSTROM, A",1994,"EFFECT OF TEMPERATURE AND LIGHT ON THE GROWTH OF MICRO-PLANKTON NANO-PLANKTON AND PICO-PLANKTON - IMPACT ON ALGAL SUCCESSION","MARINE BIOLOGY",1,"No exact experiment duration given (3-4 weeks)",NA,"Table 2","annual","1989-1990","Lab","coastal",63.52,19.8,"Baltic Sea, Sweden","Total phytoplankton (2-200um)","phytoplankton",24,"microcosm","bottle",0.25,NA,"no","temperature","reduced light","12",NA,"PAR",1,NA,NA,NA,3.228888889,15.421536,3.228888889,15.421536,NA,4,110,NA,100,165,560,"Biomass (µg C/L)","biomass","biom","SS",55.154,223.446,39,158,2,45,NA,40.9,162,562,"Biomass (µg C/L)",2,62.225,272.943,44,193,2,0.571,249.425,0.005,1
"1218",1218,1234,"723","ANDERSSON, A; HAECKY, P; HAGSTROM, A",1994,"EFFECT OF TEMPERATURE AND LIGHT ON THE GROWTH OF MICRO-PLANKTON NANO-PLANKTON AND PICO-PLANKTON - IMPACT ON ALGAL SUCCESSION","MARINE BIOLOGY",1,"No exact experiment duration given (3-4 weeks)",NA,"Table 2","annual","1989-1990","Lab","coastal",63.52,19.8,"Baltic Sea, Sweden","Total phytoplankton (2-200um)","phytoplankton",24,"microcosm","bottle",0.25,NA,"no","temperature","reduced light","12",NA,"PAR",5,NA,NA,NA,3.228888889,15.421536,3.228888889,15.421536,NA,4,110,NA,100,165,708,"Biomass (µg C/L)","biomass","biom","SS",55.154,272.943,39,193,2,45,NA,40.9,162,364,"Biomass (µg C/L)",2,62.225,241.831,44,171,2,0.571,257.857,-0.762,1.073
"1219",1219,1235,"723","ANDERSSON, A; HAECKY, P; HAGSTROM, A",1994,"EFFECT OF TEMPERATURE AND LIGHT ON THE GROWTH OF MICRO-PLANKTON NANO-PLANKTON AND PICO-PLANKTON - IMPACT ON ALGAL SUCCESSION","MARINE BIOLOGY",1,"No exact experiment duration given (3-4 weeks)",NA,"Table 2","annual","1989-1990","Lab","coastal",63.52,19.8,"Baltic Sea, Sweden","Total phytoplankton (2-200um)","phytoplankton",24,"microcosm","bottle",0.25,NA,"no","temperature","reduced light","12",NA,"PAR",10,NA,NA,NA,3.228888889,15.421536,3.228888889,15.421536,NA,4,110,NA,100,165,410,"Biomass (µg C/L)","biomass","biom","SS",55.154,121.622,39,86,2,45,NA,40.9,162,453,"Biomass (µg C/L)",2,62.225,206.475,44,146,2,0.571,169.446,0.145,1.003
"1220",1220,1236,"726","ABAL, EG; LONERAGAN, N; BOWEN, P; PERRY, CJ; UDY, JW; DENNISON, WC",1994,"PHYSIOLOGICAL AND MORPHOLOGICAL RESPONSES OF THE SEAGRASS ZOSTERA-CAPRICORNI ASCHERS TO LIGHT-INTENSITY","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiances as % of total ambient sunlight",NA,"Fig 2","fall","1992","Lab","coastal",-27.58,153.32,"Moreton Bay, Australia","Zostera capricorni","seagrass",62,"mesocosm","fiberglass tank",NA,NA,"unknown","none","shading screen","natural",NA,"PAR",23,NA,NA,35,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.745,"Chl a+b/dm2","biomass","biom","SS",NA,0.286,NA,0.128,5,NA,NA,50,NA,1.808,"Chl a+b/dm2",1,NA,0.686,NA,0.307,5,0.903,0.526,0.108,0.401
"1221",1221,1237,"726","ABAL, EG; LONERAGAN, N; BOWEN, P; PERRY, CJ; UDY, JW; DENNISON, WC",1994,"PHYSIOLOGICAL AND MORPHOLOGICAL RESPONSES OF THE SEAGRASS ZOSTERA-CAPRICORNI ASCHERS TO LIGHT-INTENSITY","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiances as % of total ambient sunlight",NA,"Fig 2","fall","1992","Lab","coastal",-27.58,153.32,"Moreton Bay, Australia","Zostera capricorni","seagrass",62,"mesocosm","fiberglass tank",NA,NA,"unknown","none","shading screen","natural",NA,"PAR",23,NA,NA,35,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.745,"Chl a+b/dm2","biomass","biom","SS",NA,0.286,NA,0.128,5,NA,NA,30,NA,2.85,"Chl a+b/dm2",1,NA,0.845,NA,0.378,5,0.903,0.631,1.582,0.525
"1222",1222,1238,"726","ABAL, EG; LONERAGAN, N; BOWEN, P; PERRY, CJ; UDY, JW; DENNISON, WC",1994,"PHYSIOLOGICAL AND MORPHOLOGICAL RESPONSES OF THE SEAGRASS ZOSTERA-CAPRICORNI ASCHERS TO LIGHT-INTENSITY","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiances as % of total ambient sunlight",NA,"Fig 2","fall","1992","Lab","coastal",-27.58,153.32,"Moreton Bay, Australia","Zostera capricorni","seagrass",62,"mesocosm","fiberglass tank",NA,NA,"unknown","none","shading screen","natural",NA,"PAR",23,NA,NA,35,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.745,"Chl a+b/dm2","biomass","biom","SS",NA,0.286,NA,0.128,5,NA,NA,20,NA,3.281,"Chl a+b/dm2",1,NA,0.675,NA,0.302,5,0.903,0.519,2.675,0.758
"1223",1223,1239,"726","ABAL, EG; LONERAGAN, N; BOWEN, P; PERRY, CJ; UDY, JW; DENNISON, WC",1994,"PHYSIOLOGICAL AND MORPHOLOGICAL RESPONSES OF THE SEAGRASS ZOSTERA-CAPRICORNI ASCHERS TO LIGHT-INTENSITY","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiances as % of total ambient sunlight",NA,"Fig 2","fall","1992","Lab","coastal",-27.58,153.32,"Moreton Bay, Australia","Zostera capricorni","seagrass",62,"mesocosm","fiberglass tank",NA,NA,"unknown","none","shading screen","natural",NA,"PAR",23,NA,NA,35,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.745,"Chl a+b/dm2","biomass","biom","SS",NA,0.286,NA,0.128,5,NA,NA,15,NA,2.913,"Chl a+b/dm2",1,NA,0.709,NA,0.317,5,0.903,0.541,1.952,0.59
"1224",1224,1240,"726","ABAL, EG; LONERAGAN, N; BOWEN, P; PERRY, CJ; UDY, JW; DENNISON, WC",1994,"PHYSIOLOGICAL AND MORPHOLOGICAL RESPONSES OF THE SEAGRASS ZOSTERA-CAPRICORNI ASCHERS TO LIGHT-INTENSITY","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"seagrass, irradiances as % of total ambient sunlight",NA,"Fig 2","fall","1992","Lab","coastal",-27.58,153.32,"Moreton Bay, Australia","Zostera capricorni","seagrass",62,"mesocosm","fiberglass tank",NA,NA,"unknown","none","shading screen","natural",NA,"PAR",23,NA,NA,35,NA,NA,NA,NA,NA,0,NA,NA,100,NA,1.745,"Chl a+b/dm2","biomass","biom","SS",NA,0.286,NA,0.128,5,NA,NA,5,NA,2.781,"Chl a+b/dm2",1,NA,0.653,NA,0.292,5,0.903,0.504,1.856,0.572
"1225",1225,1241,"737","TADROS, MG; SMITH, W; JOSEPH, B; PHILLIPS, J",1993,"Yield and quality of cyanobacteria Spirulina maxima in continuous culture in response to light intensity","APPLIED BIOCHEMISTRY AND BIOTECHNOLOGY",1,"constant volume maintained by addition of medium and outflow","No STD or STE given",NA,NA,NA,"Lab","culture",NA,NA,NA,"Spirulina maxima","phytoplankton",NA,"microcosm","chemostat",2,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1226",1226,1242,"739","STRAMSKI, D; ROSENBERG, G; LEGENDRE, L",1993,"PHOTOSYNTHETIC AND OPTICAL-PROPERTIES OF THE MARINE CHLOROPHYTE DUNALIELLA-TERTIOLECTA GROWN UNDER FLUCTUATING LIGHT CAUSED BY SURFACE-WAVE FOCUSING","MARINE BIOLOGY",1,"5 day acclimation prior to experminet begin, cells always harvested at begin of dark cycle","No replicates for LL, no STD for LL",NA,NA,NA,"Lab","culture",NA,NA,NA,"Dunaliella tertiolecta","phytoplankton",7,NA,"round dish",0.28,NA,"no","interval","shading screen","14",NA,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,800,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,45,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1227",1227,1243,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,28.3,NA,16,NA,27,"Growth rate (mg/g/d)",2,NA,17.157,NA,2.9,35,0.989,17.157,-0.865,0.062
"1228",1228,1244,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1229",1229,1245,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1230",1230,1246,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,24.2,NA,81.2,NA,27.3,"Growth rate (mg/g/d)",2,NA,18.659,NA,3.2,34,0.989,19.411,-0.805,0.063
"1231",1231,1247,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1232",1232,1248,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1233",1233,1249,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,47.5,NA,26.9,NA,41.1,"Growth rate (mg/g/d)",2,NA,523.619,NA,89.8,34,0.988,380.314,-0.028,0.06
"1234",1234,1250,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1235",1235,1251,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","spring","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,7,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1236",1236,1252,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,28.3,NA,16,NA,27,"Growth rate (mg/g/d)",2,NA,17.157,NA,2.9,35,0.989,17.157,-0.865,0.062
"1237",1237,1253,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,18.5,NA,10.5,NA,35.9,"Growth rate (mg/g/d)",2,NA,19.8,NA,3.3,36,0.989,18.545,-0.325,0.057
"1238",1238,1254,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1239",1239,1255,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,24.2,NA,81.2,NA,27.3,"Growth rate (mg/g/d)",2,NA,18.659,NA,3.2,34,0.989,19.411,-0.805,0.063
"1240",1240,1256,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,12.1,NA,40.6,NA,33.2,"Growth rate (mg/g/d)",2,NA,18.6,NA,3.1,36,0.989,19.361,-0.506,0.058
"1241",1241,1257,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1242",1242,1258,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,47.5,NA,26.9,NA,41.1,"Growth rate (mg/g/d)",2,NA,523.619,NA,89.8,34,0.988,380.314,-0.028,0.06
"1243",1243,1259,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,59.4,NA,33.6,NA,65,"Growth rate (mg/g/d)",2,NA,157.401,NA,27.4,33,0.988,133.84,0.098,0.061
"1244",1244,1260,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","summer","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,21,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1245",1245,1261,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,28.3,NA,16,NA,27,"Growth rate (mg/g/d)",2,NA,17.157,NA,2.9,35,0.989,17.157,-0.865,0.062
"1246",1246,1262,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,18.5,NA,10.5,NA,35.9,"Growth rate (mg/g/d)",2,NA,19.8,NA,3.3,36,0.989,18.545,-0.325,0.057
"1247",1247,1263,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, plants","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,47.3,NA,100,NA,42,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,17.157,NA,2.9,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1248",1248,1264,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,24.2,NA,81.2,NA,27.3,"Growth rate (mg/g/d)",2,NA,18.659,NA,3.2,34,0.989,19.411,-0.805,0.063
"1249",1249,1265,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,12.1,NA,40.6,NA,33.2,"Growth rate (mg/g/d)",2,NA,18.6,NA,3.1,36,0.989,19.361,-0.506,0.058
"1250",1250,1266,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, leaves","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,29.8,NA,100,NA,43.1,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,20.115,NA,3.4,35,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1251",1251,1267,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,47.5,NA,26.9,NA,41.1,"Growth rate (mg/g/d)",2,NA,523.619,NA,89.8,34,0.988,380.314,-0.028,0.06
"1252",1252,1268,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,59.4,NA,33.6,NA,65,"Growth rate (mg/g/d)",2,NA,157.401,NA,27.4,33,0.988,133.84,0.098,0.061
"1253",1253,1269,"740","OLESEN, B; SANDJENSEN, K",1993,"SEASONAL ACCLIMATIZATION OF EELGRASS ZOSTERA-MARINA GROWTH TO LIGHT","MARINE ECOLOGY PROGRESS SERIES",1,"seagrass, 3 different growth temperatures (7,15,21),5 day acclimatization in low light (30umol) prior experiment start","Not possible to get both Ctrl and trt values for all different temperatures","Table 1","fall","1992","Lab","coastal",56.13,10.36,"Aarhus Bight, Denmark","Zostera marina, rhizomes","seagrass",28,"lab plot","plastic pots in aquaria",20,NA,"no","nutrients","shading screen","16",NA,NA,15,8.2,NA,20,NA,NA,NA,NA,NA,0,176.7,NA,100,NA,51.7,"Growth rate (mg/g/d)","growth rate","biom","dSS",NA,105.125,NA,18.3,33,NA,NA,NA,NA,NA,"Growth rate (mg/g/d)",2,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1254",1254,1270,"745","MARKAGER, S",1993,"LIGHT-ABSORPTION AND QUANTUM YIELD FOR GROWTH IN 5 SPECIES OF MARINE MACROALGAE","JOURNAL OF PHYCOLOGY",1,NA,"No STD or STE given, just 95% CI",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1255",1255,1271,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Floating macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.13,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.318,NA,0.159,4,150,NA,30,NA,1.062,"gdw/aquarium (2l volume)",2,NA,0.148,NA,0.074,4,0.87,0.248,-0.238,0.504
"1256",1256,1272,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available","All values not available","Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Attached green macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,NA,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,NA,NA,NA,4,150,NA,30,NA,3.169,"gdw/aquarium (2l volume)",2,NA,0.434,NA,0.217,4,0.87,NA,NA,NA
"1257",1257,1273,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Floating macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.13,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.318,NA,0.159,4,275,NA,55,NA,1.138,"gdw/aquarium (2l volume)",2,NA,0.468,NA,0.234,4,0.87,0.4,0.017,0.5
"1258",1258,1274,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available","All values not available","Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Attached green macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,NA,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,NA,NA,NA,4,275,NA,55,NA,1.67,"gdw/aquarium (2l volume)",2,NA,0.7,NA,0.35,4,0.87,NA,NA,NA
"1259",1259,1275,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Floating macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.141,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,150,NA,30,NA,0.596,"gdw/aquarium (2l volume)",2,NA,0.152,NA,0.076,4,0.87,0.123,-3.838,1.42
"1260",1260,1276,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available","All values not available","Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Attached green macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,NA,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,NA,NA,NA,4,150,NA,30,NA,1.743,"gdw/aquarium (2l volume)",2,NA,0.498,NA,0.249,4,0.87,NA,NA,NA
"1261",1261,1277,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Floating macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.141,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,275,NA,55,NA,1.101,"gdw/aquarium (2l volume)",2,NA,0.086,NA,0.043,4,0.87,0.086,-0.404,0.51
"1262",1262,1278,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available","All values not available","Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Attached green macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,NA,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,275,NA,55,NA,NA,"gdw/aquarium (2l volume)",2,NA,NA,NA,NA,4,0.87,NA,NA,NA
"1263",1263,1279,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Floating macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.384,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,150,NA,30,NA,0.887,"gdw/aquarium (2l volume)",2,NA,0.194,NA,0.097,4,0.87,0.15,-2.88,1.018
"1264",1264,1280,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available","All values not available","Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Attached green macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,NA,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,NA,NA,NA,4,150,NA,30,NA,2.646,"gdw/aquarium (2l volume)",2,NA,0.43,NA,0.215,4,0.87,NA,NA,NA
"1265",1265,1281,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Floating macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.384,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,275,NA,55,NA,1.248,"gdw/aquarium (2l volume)",2,NA,0.43,NA,0.215,4,0.87,0.31,-0.381,0.509
"1266",1266,1282,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available","All values not available","Fig 2","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Attached green macroalgae","macroalgae",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,NA,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,NA,NA,NA,4,275,NA,55,NA,NA,"gdw/aquarium (2l volume)",2,NA,NA,NA,NA,4,0.87,NA,NA,NA
"1267",1267,1283,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 3","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total cyanobacteria","phytobenthos",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.774,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.516,NA,0.258,4,150,NA,30,NA,0.058,"gdw/aquarium (2l volume)",2,NA,0.22,NA,0.11,4,0.87,0.397,-3.762,1.385
"1268",1268,1284,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 3","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total cyanobacteria","phytobenthos",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.774,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.516,NA,0.258,4,275,NA,55,NA,1.058,"gdw/aquarium (2l volume)",2,NA,0.812,NA,0.406,4,0.87,0.68,-0.915,0.552
"1269",1269,1285,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 3","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total cyanobacteria","phytobenthos",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.655,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,1.338,NA,0.669,4,150,NA,30,NA,0.793,"gdw/aquarium (2l volume)",2,NA,0.636,NA,0.318,4,0.87,1.048,-2.376,0.853
"1270",1270,1286,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 3","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total cyanobacteria","phytobenthos",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.655,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,1.338,NA,0.669,4,275,NA,55,NA,3.931,"gdw/aquarium (2l volume)",2,NA,1.82,NA,0.91,4,0.87,1.597,0.15,0.501
"1271",1271,1287,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 3","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total cyanobacteria","phytobenthos",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.769,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,150,NA,30,NA,1.626,"gdw/aquarium (2l volume)",2,NA,0.46,NA,0.23,4,0.87,0.331,-0.376,0.509
"1272",1272,1288,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 3","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total cyanobacteria","phytobenthos",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.769,"gdw/aquarium (2l volume)","biomass","biom","SS",NA,0.086,NA,0.043,4,275,NA,55,NA,3.624,"gdw/aquarium (2l volume)",2,NA,0.658,NA,0.329,4,0.87,0.469,3.438,1.239
"1273",1273,1289,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 4","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total phytoplankton","phytoplankton",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.034,"Chl a (µg/L)","biomass","biom","SS",NA,1.99,NA,0.995,4,150,NA,30,NA,7.832,"Chl a (µg/L)",2,NA,6.182,NA,3.091,4,0.87,4.592,0.909,0.552
"1274",1274,1290,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 4","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total phytoplankton","phytoplankton",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","9",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.034,"Chl a (µg/L)","biomass","biom","SS",NA,1.99,NA,0.995,4,275,NA,55,NA,3.972,"Chl a (µg/L)",2,NA,3.386,NA,1.693,4,0.87,2.777,0.294,0.505
"1275",1275,1291,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 4","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total phytoplankton","phytoplankton",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.773,"Chl a (µg/L)","biomass","biom","SS",NA,0.512,NA,0.256,4,150,NA,30,NA,5.668,"Chl a (µg/L)",2,NA,2.124,NA,1.062,4,0.87,1.545,1.067,0.571
"1276",1276,1292,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 4","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total phytoplankton","phytoplankton",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","12",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.773,"Chl a (µg/L)","biomass","biom","SS",NA,0.512,NA,0.256,4,275,NA,55,NA,2.762,"Chl a (µg/L)",2,NA,1.022,NA,0.511,4,0.87,0.808,-1.088,0.574
"1277",1277,1293,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 4","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total phytoplankton","phytoplankton",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.932,"Chl a (µg/L)","biomass","biom","SS",NA,0.322,NA,0.161,4,150,NA,30,NA,2.133,"Chl a (µg/L)",2,NA,0.914,NA,0.457,4,0.87,0.685,0.255,0.504
"1278",1278,1294,"747","FONG, P; ZEDLER, JB",1993,"TEMPERATURE AND LIGHT EFFECTS ON THE SEASONAL SUCCESSION OF ALGAL COMMUNITIES IN SHALLOW COASTAL LAGOONS","JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY",1,"natural mixed species assemblage experiment (macroalgae, cyanobacterial mats+epiphytes). Pre-acclimatized in low-nutrient seawater for 7 days, high light values only for floating macroalgae available",NA,"Fig 4","summer","1988","Lab","coastal",33,-117.28,"San Elijo Lagoon, San Diego, USA","Total phytoplankton","phytoplankton",30,"microcosm","Aquaria",2,NA,"unknown","nutrients","reduced light","15",NA,"PAR",22,NA,NA,30,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.932,"Chl a (µg/L)","biomass","biom","SS",NA,0.322,NA,0.161,4,275,NA,55,NA,1.364,"Chl a (µg/L)",2,NA,0.484,NA,0.242,4,0.87,0.411,-1.202,0.59
"1279",1279,1295,"750","HENLEY, WJ",1992,"GROWTH AND PHOTOSYNTHESIS OF ULVA-ROTUNDATA (CHLOROPHYTA) AS A FUNCTION OF TEMPERATURE AND SQUARE-WAVE IRRADIANCE IN INDOOR CULTURE","JOURNAL OF PHYCOLOGY",1,NA,"No STD or STE given, vague duration",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1280",1280,1296,"753","PEREZ, M; ROMERO, J",1992,"PHOTOSYNTHETIC RESPONSE TO LIGHT AND TEMPERATURE OF THE SEAGRASS CYMODOCEA-NODOSA AND THE PREDICTION OF ITS SEASONALITY","AQUATIC BOTANY",1,"seagrass","no light treatment, no accurate duration, only seasonal patterns",NA,NA,NA,NA,NA,40.71,0.87,"Ebro Delta, Spain",NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1281",1281,1297,"754","MARTINEZ, R",1992,"RESPIRATION AND RESPIRATORY ELECTRON-TRANSPORT ACTIVITY IN MARINE-PHYTOPLANKTON - GROWTH-RATE DEPENDENCE AND LIGHT ENHANCEMENT","JOURNAL OF PLANKTON RESEARCH",1,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1282",1282,1298,"758","REY, F",1991,"PHOTOSYNTHESIS-IRRADIANCE RELATIONSHIPS IN NATURAL PHYTOPLANKTON POPULATIONS OF THE BARENTS SEA","POLAR RESEARCH",1,"very relevant review","No actual experiment, a review",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1283",1283,1299,"766","SAKSHAUG, E; JOHNSEN, G; ANDRESEN, K; VERNET, M",1991,"MODELING OF LIGHT-DEPENDENT ALGAL PHOTOSYNTHESIS AND GROWTH - EXPERIMENTS WITH THE BARENTS SEA DIATOMS THALASSIOSIRA-NORDENSKIOELDII AND CHAETOCEROS-FURCELLATUS","DEEP-SEA RESEARCH PART A-OCEANOGRAPHIC RESEARCH PAPERS",1,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1284",1284,1300,"770","LI, WKW; DICKIE, PM",1991,"LIGHT AND DARK C-14 UPTAKE IN DIMLY-LIT OLIGOTROPHIC WATERS - RELATION TO BACTERIAL-ACTIVITY","JOURNAL OF PLANKTON RESEARCH",1,"Not found, not even on Scihub","Not found, not even on Scihub",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1285",1285,1301,"774","KELLER, AA",1988,"ESTIMATING PHYTOPLANKTON PRODUCTIVITY FROM LIGHT AVAILABILITY AND Biomass IN THE MERL MESOCOSMS AND NARRAGANSETT BAY","MARINE ECOLOGY PROGRESS SERIES",1,NA,"no light treatment",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1286",1286,1302,"775","SHEARER, JA; FEE, EJ; DEBRUYN, ER; DECLERCQ, DR",1987,"PHYTOPLANKTON PRIMARY PRODUCTION AND LIGHT ATTENUATION RESPONSES TO THE EXPERIMENTAL ACIDIFICATION OF A SMALL CANADIAN SHIELD LAKE","CANADIAN JOURNAL OF FISHERIES AND AQUATIC SCIENCES",2,"no abstract available","no abstract available",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1287",1287,1303,"777","ELSER, JJ; KIMMEL, BL",1985,"PHOTOINHIBITION OF TEMPERATE LAKE PHYTOPLANKTON BY NEAR-SURFACE IRRADIANCE - EVIDENCE FROM VERTICAL PROFILES AND FIELD EXPERIMENTS","JOURNAL OF PHYCOLOGY",2,"no abstract available","no abstract available",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1288",1288,1304,"778","VINER, AB",1984,"LABORATORY EXPERIMENTS ON THE EFFECTS OF LIGHT AND TEMPERATURE ON THE UPTAKE OF NUTRIENTS BY LAKE ROTONGAIO PHYTOPLANKTON","NEW ZEALAND JOURNAL OF MARINE AND FRESHWATER RESEARCH",2,"no abstract available","no abstract available",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1289",1289,1305,"779","DENNISON, WC; ALBERTE, RS",1982,"PHOTOSYNTHETIC RESPONSES OF ZOSTERA-MARINA L (EELGRASS) TO INSITU MANIPULATIONS OF LIGHT-INTENSITY","OECOLOGIA",1,"seagrass","No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1290",1290,1306,"780","DENNISON, WC; MAUZERALL, D; ALBERTE, RS",1981,"PHOTOSYNTHETIC RESPONSE OF ZOSTERA-MARINA (EELGRASS) TO INSITU MANIPULATIONS OF LIGHT","BIOLOGICAL BULLETIN",1,"seagrass","No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1291",1291,1307,"783","NEWBURGH, RG; HEROUX, L; PHIPPS, TE",1978,"COMMENT ON MARINOVS LIGHT VELOCITY EXPERIMENT","PHYSICS LETTERS A",NA,"no abstract available","no abstract available",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1292",1292,1308,"784","BEARDALL, J; MORRIS, I",1976,"CONCEPT OF LIGHT-INTENSITY ADAPTATION IN MARINE-PHYTOPLANKTON - SOME EXPERIMENTS WITH PHAEODACTYLUM-TRICORNUTUM","MARINE BIOLOGY",NA,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1293",1293,1309,"785","SCHONE, HK",1972,"EXPERIMENTAL INVESTIGATIONS ON ECOLOGY OF MARINE DIATOM THALASSIOSIRA-ROTULA .1. TEMPERATURE AND LIGHT","MARINE BIOLOGY",NA,"no abstract available","no abstract available",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1294",1294,1310,"786","SMAYDA, TJ",1969,"EXPERIMENTAL OBSERVATIONS ON INFLUENCE OF TEMPERATURE, LIGHT, AND SALINITY ON CELL DIVISION OF MARINE DIATOM, DETONULA CONFERVACEA (CLEVE) GRAN","JOURNAL OF PHYCOLOGY",NA,NA,"No STD or STE given",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,"unknown","none",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA
"1295",1295,1311,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Table 3",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",32,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,1.64,"growth rate","biom","biom","dSS",NA,0.02,NA,0.01,4,50,NA,50,NA,1.71,"growth rate",2,NA,0.11,NA,0.055,4,0.869565217,0.079056942,0.769945865,0.53705104
"1296",1296,1312,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Table 3",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",32,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,1.15,"growth rate","biom","biom","dSS",NA,0.03,NA,0.015,4,50,NA,50,NA,1.27,"growth rate",2,NA,0.04,NA,0.02,4,0.869565217,0.035355339,2.951402217,1.04442344
"1297",1297,1313,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",2,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,594.9775297,"cell /mL","abundance","biom","SS",NA,NA,NA,NA,4,50,NA,50,NA,182.6117,"cell /mL",2,NA,NA,NA,NA,4,0.869565217,NA,NA,NA
"1298",1298,1314,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",5,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,18702.80911,"cell /mL","abundance","biom","SS",NA,4948.38952,NA,2474.19476,4,50,NA,50,NA,10043.1275,"cell /mL",2,NA,2060.792872,NA,1030.396436,4,0.869565217,3790.344714,-1.986668373,0.746678201
"1299",1299,1315,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",7,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,64862.91169,"cell /mL","abundance","biom","SS",NA,6598.888788,NA,3299.444394,4,50,NA,50,NA,45481.7194,"cell /mL",2,NA,4123.657933,NA,2061.828967,4,0.869565217,5502.267169,-3.062957535,1.086356804
"1300",1300,1316,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",9,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,93704.68703,"cell /mL","abundance","biom","SS",NA,23504.85022,NA,11752.42511,4,50,NA,50,NA,82982.1403,"cell /mL",2,NA,21031.69155,NA,10515.84578,4,0.869565217,22302.5787,-0.418066171,0.510923708
"1301",1301,1317,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",12,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,59029.69707,"cell /mL","abundance","biom","SS",NA,18144.09491,NA,9072.047453,4,50,NA,50,NA,62740.9892,"cell /mL",2,NA,16905.96143,NA,8452.980716,4,0.869565217,17535.95894,0.18403388,0.502116779
"1302",1302,1318,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",3,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,170.1785969,"cell /mL","abundance","biom","SS",NA,NA,NA,NA,4,50,NA,50,NA,993.8741,"cell /mL",2,NA,NA,NA,NA,4,0.869565217,NA,NA,NA
"1303",1303,1319,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",5,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,146.3484128,"cell /mL","abundance","biom","SS",NA,NA,NA,NA,4,50,NA,50,NA,970.0439,"cell /mL",2,NA,NA,NA,NA,4,0.869565217,NA,NA,NA
"1304",1304,1320,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",7,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,3833.810369,"cell /mL","abundance","biom","SS",NA,2060.792872,NA,1030.396436,4,50,NA,50,NA,2183.3111,"cell /mL",2,NA,2886.560553,NA,1443.280277,4,0.869565217,2507.897435,-0.572278888,0.520468945
"1305",1305,1321,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,52043.30877,"cell /mL","abundance","biom","SS",NA,14845.16856,NA,7422.58428,4,50,NA,50,NA,43383.6271,"cell /mL",2,NA,6598.888788,NA,3299.444394,4,0.869565217,11487.47933,-0.655510034,0.526855838
"1306",1306,1322,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",12,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,34700.11527,"cell /mL","abundance","biom","SS",NA,8658.645565,NA,4329.322782,4,50,NA,50,NA,35523.8108,"cell /mL",2,NA,825.7676816,NA,412.8838408,4,0.869565217,6150.367277,0.11645759,0.500847648
"1307",1307,1323,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",14,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,37975.21143,"cell /mL","abundance","biom","SS",NA,8246.279772,NA,4123.139886,4,50,NA,50,NA,40860.7359,"cell /mL",2,NA,16083.30203,NA,8041.651017,4,0.869565217,12780.33126,0.19632916,0.502409071
"1308",1308,1324,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",17,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,73813.73603,"cell /mL","abundance","biom","SS",NA,34226.36085,NA,17113.18042,4,50,NA,50,NA,54844.9095,"cell /mL",2,NA,29072.82452,NA,14536.41226,4,0.869565217,31754.3139,-0.519445383,0.516863969
"1309",1309,1325,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",19,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,63068.39522,"cell /mL","abundance","biom","SS",NA,18143.05881,NA,9071.529406,4,50,NA,50,NA,61417.896,"cell /mL",2,NA,28041.91004,NA,14020.95502,4,0.869565217,23616.93568,-0.060770659,0.500230817
"1310",1310,1326,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",21,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,76240.27042,"cell /mL","abundance","biom","SS",NA,14431.76667,NA,7215.883336,4,50,NA,50,NA,88610.2081,"cell /mL",2,NA,7834.950073,NA,3917.475037,4,0.869565217,11611.68231,0.926348766,0.553632627
"1311",1311,1327,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",24,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,84037.92108,"cell /mL","abundance","biom","SS",NA,20618.28967,NA,10309.14483,4,50,NA,50,NA,76614.3007,"cell /mL",2,NA,9073.083548,NA,4536.541774,4,0.869565217,15928.50768,-0.405268478,0.510265159
"1312",1312,1328,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",26,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,79478.06716,"cell /mL","abundance","biom","SS",NA,4536.023727,NA,2268.011863,4,50,NA,50,NA,102569.5155,"cell /mL",2,NA,13195.70539,NA,6597.852693,4,0.869565217,9866.664885,2.035086883,0.758848664
"1313",1313,1329,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",28,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,76979.00613,"cell /mL","abundance","biom","SS",NA,7010.218487,NA,3505.109243,4,50,NA,50,NA,73679.0437,"cell /mL",2,NA,33402.66535,NA,16701.33268,4,0.869565217,24133.80633,-0.118900952,0.50088359
"1314",1314,1330,"793","Ajani, PA; Armbrecht, LH; Kersten, O; Kohli, GS; Murray, SA",2016,"Diversity, temporal distribution and physiology of the centric diatom Leptocylindrus Cleve (Bacillariophyta) from a southern hemisphere upwelling system","DIATOM RESEARCH",1,"total duration 32 days",NA,"Fig 17",NA,"2015","Lab","culture",NA,NA,NA,"Leptocylindricus danicus","phytoplankton",32,"microcosm","culture flask",0.05,NA,"No","temp","light reduced","12",NA,NA,19,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.057593928,"cell /mL","abundance","biom","SS",NA,NA,NA,NA,4,50,NA,50,NA,1055.0037,"cell /mL",2,NA,NA,NA,NA,4,0.869565217,NA,NA,NA
"1315",1315,1331,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.005721664,"growth rate","biom","biom","dSS",NA,0.046151432,NA,0.026645542,3,10,NA,5.555555556,NA,0.0995,"growth rate",2,NA,0.013949522,NA,0.00805376,3,0.8,0.034092109,-21.26536199,38.3513017
"1316",1316,1332,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.005721664,"growth rate","biom","biom","dSS",NA,0.046151432,NA,0.026645542,3,20,NA,11.11111111,NA,0.2276,"growth rate",2,NA,0.016141338,NA,0.009319206,3,0.8,0.03457237,-18.00620166,27.68527484
"1317",1317,1333,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.005721664,"growth rate","biom","biom","dSS",NA,0.046151432,NA,0.026645542,3,50,NA,27.77777778,NA,0.5476,"growth rate",2,NA,0.022030788,NA,0.012719481,3,0.8,0.036161515,-10.13427716,9.225297797
"1318",1318,1334,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.005721664,"growth rate","biom","biom","dSS",NA,0.046151432,NA,0.026645542,3,80,NA,44.44444444,NA,0.7319,"growth rate",2,NA,0.041187115,NA,0.023779392,3,0.8,0.043739759,-5.008862254,2.757391756
"1319",1319,1335,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.005721664,"growth rate","biom","biom","dSS",NA,0.046151432,NA,0.026645542,3,120,NA,66.66666667,NA,0.7728,"growth rate",2,NA,0.045372838,NA,0.02619602,3,0.8,0.045763791,-4.071033253,2.047775979
"1320",1320,1336,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.356796117,"growth rate","biom","biom","dSS",NA,0.02184466,NA,0.01261202,3,10,NA,5.555555556,NA,0.0898,"growth rate",2,NA,0.029126214,NA,0.016816027,3,0.8,0.025744179,-39.37170558,129.8442667
"1321",1321,1337,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.356796117,"growth rate","biom","biom","dSS",NA,0.02184466,NA,0.01261202,3,20,NA,11.11111111,NA,0.2282,"growth rate",2,NA,0.02184466,NA,0.01261202,3,0.8,0.02184466,-41.33333333,143.037037
"1322",1322,1338,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.356796117,"growth rate","biom","biom","dSS",NA,0.02184466,NA,0.01261202,3,50,NA,27.77777778,NA,0.6796,"growth rate",2,NA,0.014563107,NA,0.008408014,3,0.8,0.018564391,-29.18208091,71.63282051
"1323",1323,1339,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.356796117,"growth rate","biom","biom","dSS",NA,0.02184466,NA,0.01261202,3,80,NA,44.44444444,NA,0.9345,"growth rate",2,NA,0.036407767,NA,0.021020034,3,0.8,0.030022614,-11.253653,11.22039216
"1324",1324,1340,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.356796117,"growth rate","biom","biom","dSS",NA,0.02184466,NA,0.01261202,3,120,NA,66.66666667,NA,1.0583,"growth rate",2,NA,0.029126214,NA,0.016816027,3,0.8,0.025744179,-9.277240969,7.838933333
"1325",1325,1341,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,0.875,"growth rate","biom","biom","dSS",NA,0.0234375,NA,0.013531647,3,10,NA,5.555555556,NA,0.1094,"growth rate",2,NA,0.015625,NA,0.009021098,3,0.8,0.019918045,-30.75100999,79.46871795
"1326",1326,1342,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,0.875,"growth rate","biom","biom","dSS",NA,0.0234375,NA,0.013531647,3,20,NA,11.11111111,NA,0.2344,"growth rate",2,NA,0.0234375,NA,0.013531647,3,0.8,0.0234375,-21.86666667,40.51259259
"1327",1327,1343,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,0.875,"growth rate","biom","biom","dSS",NA,0.0234375,NA,0.013531647,3,50,NA,27.77777778,NA,0.4922,"growth rate",2,NA,0.0234375,NA,0.013531647,3,0.8,0.0234375,-13.06666667,14.89481481
"1328",1328,1344,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,0.875,"growth rate","biom","biom","dSS",NA,0.0234375,NA,0.013531647,3,80,NA,44.44444444,NA,0.6094,"growth rate",2,NA,0.0234375,NA,0.013531647,3,0.8,0.0234375,-9.066666667,7.517037037
"1329",1329,1345,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,0.875,"growth rate","biom","biom","dSS",NA,0.0234375,NA,0.013531647,3,120,NA,66.66666667,NA,0.8281,"growth rate",2,NA,0.0234375,NA,0.013531647,3,0.8,0.0234375,-1.6,0.88
"1330",1330,1346,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.030612245,"growth rate","biom","biom","dSS",NA,0.022959184,NA,0.013255491,3,10,NA,5.555555556,NA,0.1122,"growth rate",2,NA,0.022959184,NA,0.013255491,3,0.8,0.022959184,-32,86
"1331",1331,1347,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.030612245,"growth rate","biom","biom","dSS",NA,0.022959184,NA,0.013255491,3,20,NA,11.11111111,NA,0.227,"growth rate",2,NA,0.030612245,NA,0.017673988,3,0.8,0.027057657,-23.75878785,47.70666667
"1332",1332,1348,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.030612245,"growth rate","biom","biom","dSS",NA,0.022959184,NA,0.013255491,3,50,NA,27.77777778,NA,0.6173,"growth rate",2,NA,0.022959184,NA,0.013255491,3,0.8,0.022959184,-14.4,17.94666667
"1333",1333,1349,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.030612245,"growth rate","biom","biom","dSS",NA,0.022959184,NA,0.013255491,3,80,NA,44.44444444,NA,0.7781,"growth rate",2,NA,0.015306122,NA,0.008836994,3,0.8,0.019511554,-10.35493194,9.602051282
"1334",1334,1350,"802","Hu, ZX; Mulholland, MR; Xu, N; Duan, SS",2016,"Effects of temperature, irradiance and pCO(2) on the growth and nitrogen utilization of Prorocentrum donghaiense","AQUATIC MICROBIAL ECOLOGY",1,"different N sources",NA,"Fig 2",NA,NA,"Lab","culture",NA,NA,NA,"Prorocentrum donghaiense","phytoplankton",9,"microcosm","culture flask",0.35,NA,"No","nut","gradient","12",NA,NA,23,NA,NA,NA,3.12,50,NA,NA,NA,2,180,NA,100,NA,1.030612245,"growth rate","biom","biom","dSS",NA,0.022959184,NA,0.013255491,3,120,NA,66.66666667,NA,0.9311,"growth rate",2,NA,0.022959184,NA,0.013255491,3,0.8,0.022959184,-3.466666667,1.668148148
"1335",1335,1351,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 3","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,8.06,NA,36,NA,NA,NA,NA,NA,0,300,NA,100,NA,79,"production at saturating irradiance","PP","phys","dQ",NA,39,NA,13,9,90,NA,30,NA,87,"production at saturating irradiance",1,NA,24,NA,8,9,0.952380952,32.38054972,0.235297044,0.223760131
"1336",1336,1352,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 3","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,8,NA,35.9,NA,NA,NA,NA,NA,0,300,NA,100,NA,85,"production at saturating irradiance","PP","phys","dQ",NA,27,NA,9,9,90,NA,30,NA,92,"production at saturating irradiance",1,NA,27,NA,9,9,0.952380952,27,0.24691358,0.223915731
"1337",1337,1353,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 3","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,7.86,NA,36.2,NA,NA,NA,NA,NA,0,300,NA,100,NA,118,"production at saturating irradiance","PP","phys","dQ",NA,66,NA,22,9,90,NA,30,NA,96,"production at saturating irradiance",1,NA,30,NA,10,9,0.952380952,51.26402247,-0.408715117,0.226862446
"1338",1338,1354,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 3","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,7.74,NA,36.3,NA,NA,NA,NA,NA,0,300,NA,100,NA,128,"production at saturating irradiance","PP","phys","dQ",NA,45,NA,15,9,90,NA,30,NA,121,"production at saturating irradiance",1,NA,57,NA,19,9,0.952380952,51.35172831,-0.129823608,0.222690394
"1339",1339,1355,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 4","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,8.06,NA,36,NA,NA,NA,NA,NA,0,300,NA,100,NA,1,"calcification rate","productivity","phys","dQ",NA,1.2,NA,0.4,9,90,NA,30,NA,0.1,"production at saturating irradiance",1,NA,2.7,NA,0.9,9,0.952380952,2.089258242,-0.410261805,0.226897632
"1340",1340,1356,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 4","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,8,NA,35.9,NA,NA,NA,NA,NA,0,300,NA,100,NA,-0.7,"calcification rate","productivity","phys","dQ",NA,1.8,NA,0.6,9,90,NA,30,NA,0.5,"production at saturating irradiance",1,NA,2.1,NA,0.7,9,0.952380952,1.955760722,0.584354277,0.231707498
"1341",1341,1357,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 4","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,7.86,NA,36.2,NA,NA,NA,NA,NA,0,300,NA,100,NA,1.9,"calcification rate","productivity","phys","dQ",NA,2.7,NA,0.9,9,90,NA,30,NA,1.4,"production at saturating irradiance",1,NA,2.4,NA,0.8,9,0.952380952,2.554407955,-0.186419117,0.223187558
"1342",1342,1358,"811","Peach, KE; Koch, MS; Blackwelder, PL",2016,"Effects of elevated pCO(2) and irradiance on growth, photosynthesis and calcification in Halimeda discoidea","MARINE ECOLOGY PROGRESS SERIES",1,NA,NA,"Table 4","winter","2013","Lab","coastal",26.327,-80.07216667,NA,"Halimeda discoidea","macroalgae",10,"microcosm","culture flask",9.5,NA,"No","pCo2","light reduced",NA,NA,NA,26,7.74,NA,36.3,NA,NA,NA,NA,NA,0,300,NA,100,NA,0.7,"calcification rate","productivity","phys","dQ",NA,1.8,NA,0.6,9,90,NA,30,NA,0.9,"production at saturating irradiance",1,NA,3.6,NA,1.2,9,0.952380952,2.846049894,0.066926511,0.222346643
"1343",1343,1359,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Grateloupia imbricata","macroalgae",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,15.04084967,"growth rate","biom","biom","dSS",NA,7.193652802,NA,2.543340339,8,18,NA,66.66666667,NA,17.1709,"growth rate",2,NA,12.47611324,NA,4.715527565,7,0.941176471,9.985223288,0.200769016,0.269200749
"1344",1344,1360,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Grateloupia imbricata","macroalgae",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,15.04084967,"growth rate","biom","biom","dSS",NA,7.193652802,NA,2.543340339,8,11,NA,40.74074074,NA,15.3968,"growth rate",2,NA,17.21275705,NA,6.505810649,7,0.941176471,12.82999645,0.026113489,0.267879873
"1345",1345,1361,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Grateloupia imbricata","macroalgae",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,15.04084967,"growth rate","biom","biom","dSS",NA,7.193652802,NA,2.543340339,8,6,NA,22.22222222,NA,14.3697,"growth rate",2,NA,12.14270667,NA,4.589511727,7,0.941176471,9.793688847,-0.064493084,0.267995788
"1346",1346,1362,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Grateloupia imbricata","macroalgae",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,15.04084967,"growth rate","biom","biom","dSS",NA,7.193652802,NA,2.543340339,8,5,NA,18.51851852,NA,15.7761,"growth rate",2,NA,9.451230766,NA,3.341514682,8,0.945454545,8.398642855,0.08277375,0.250214109
"1347",1347,1363,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Grateloupia imbricata","macroalgae",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,15.04084967,"growth rate","biom","biom","dSS",NA,7.193652802,NA,2.543340339,8,3,NA,11.11111111,NA,10.4949,"growth rate",2,NA,13.76655632,NA,5.203269206,7,0.941176471,10.73939163,-0.398400051,0.273147896
"1348",1348,1364,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Stypopodium zonale","seaweed",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,-8.227124183,"growth rate","biom","biom","dSS",NA,3.215913525,NA,1.136997131,8,18,NA,66.66666667,NA,-10.2754,"growth rate",2,NA,4.663512706,NA,1.648800729,8,0.945454545,4.005649171,-0.48346541,0.257304338
"1349",1349,1365,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Stypopodium zonale","seaweed",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,-8.227124183,"growth rate","biom","biom","dSS",NA,3.215913525,NA,1.136997131,8,11,NA,40.74074074,NA,-11.3025,"growth rate",2,NA,4.195516279,NA,1.585756099,7,0.941176471,3.700403717,-0.782209551,0.288252202
"1350",1350,1366,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Stypopodium zonale","seaweed",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,-8.227124183,"growth rate","biom","biom","dSS",NA,3.215913525,NA,1.136997131,8,6,NA,22.22222222,NA,-14.0686,"growth rate",2,NA,5.339913281,NA,1.887944446,8,0.945454545,4.407764379,-1.252987987,0.29906184
"1351",1351,1367,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Stypopodium zonale","seaweed",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,-8.227124183,"growth rate","biom","biom","dSS",NA,3.215913525,NA,1.136997131,8,5,NA,18.51851852,NA,-12.3121,"growth rate",2,NA,3.866472203,NA,1.367004357,8,0.945454545,3.556100891,-1.086063371,0.286860426
"1352",1352,1368,"858","Ramalhosa, P; Debus, SL; Kaufmann, M; Lenz, M",2016,"A non-native macroalga is less attractive for herbivores but more susceptible to light limitation and grazing stress than a comparable native species","HELGOLAND MARINE RESEARCH",1,NA,NA,"Fig. 2","summer","2007","Lab","coastal",32.633333,-16.9,"indoor laboratory facilities at Estação de Biologia Marinha do Funchal","Stypopodium zonale","seaweed",21,"microcosm","culture flask",3.5,NA,"Yes",NA,"gradient","12",NA,NA,23,NA,NA,NA,NA,NA,NA,NA,NA,0,27,NA,100,NA,-8.227124183,"growth rate","biom","biom","dSS",NA,3.215913525,NA,1.136997131,8,3,NA,11.11111111,NA,-20.7067,"growth rate",2,NA,8.359809235,NA,2.9556389,8,0.945454545,6.33358154,-1.862906633,0.35845066
"1353",1353,1369,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,8.17,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.221969697,"growth","biom","biom","dSS",NA,0.006060606,NA,0.003499093,3,20,NA,10,NA,0.5469,"growth rate",2,NA,0.006122449,NA,0.003534798,3,0.8,0.006091606,-88.65063452,655.5779167
"1354",1354,1370,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.85,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.245454545,"growth","biom","biom","dSS",NA,0.00530303,NA,0.003061706,3,20,NA,10,NA,0.5592,"growth rate",2,NA,0.005102041,NA,0.002945665,3,0.8,0.005203506,-105.5089953,928.3456737
"1355",1355,1371,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.5,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.204545455,"growth","biom","biom","dSS",NA,0.01969697,NA,0.011372051,3,20,NA,10,NA,0.5684,"growth rate",2,NA,0.006122449,NA,0.003534798,3,0.8,0.014585181,-34.89449283,102.1354691
"1356",1356,1372,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.176515152,"growth","biom","biom","dSS",NA,0.006818182,NA,0.003936479,3,20,NA,10,NA,0.5602,"growth rate",2,NA,0.015306122,NA,0.008836994,3,0.8,0.011848312,-41.61342661,144.9731062
"1357",1357,1373,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,8.17,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.59765625,"Fv/Fm","phys","phys","dQ",NA,0.01796875,NA,0.010374263,3,20,NA,10,NA,0.65,"Fv/Fm",1,NA,0.01484375,NA,0.008570043,3,0.8,0.016480487,2.540883682,1.204674157
"1358",1358,1374,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.85,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.603125,"Fv/Fm","phys","phys","dQ",NA,0.01015625,NA,0.005863714,3,20,NA,10,NA,0.6391,"Fv/Fm",1,NA,0.00625,NA,0.003608439,3,0.8,0.008432435,3.409454162,1.635364807
"1359",1359,1375,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.5,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.63046875,"Fv/Fm","phys","phys","dQ",NA,0.0171875,NA,0.009923208,3,20,NA,10,NA,0.6523,"Fv/Fm",1,NA,0.00625,NA,0.003608439,3,0.8,0.012931989,1.353233489,0.819270073
"1360",1360,1376,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.60234375,"Fv/Fm","phys","phys","dQ",NA,0.01171875,NA,0.006765823,3,20,NA,10,NA,0.6273,"Fv/Fm",1,NA,0.00859375,NA,0.004961604,3,0.8,0.010275739,1.946331958,0.982350674
"1361",1361,1377,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,8.17,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.609022556,"Effective quantum yield in limiting light","quantum yield","phys","dQ",NA,0.010150376,NA,0.005860322,3,20,NA,10,NA,0.6068,"Effective quantum yield in limiting light",1,NA,0.013533835,NA,0.007813763,3,0.8,0.011962333,-0.150849437,0.668562963
"1362",1362,1378,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.85,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.613533835,"Effective quantum yield in limiting light","quantum yield","phys","dQ",NA,0.012406015,NA,0.007162616,3,20,NA,10,NA,0.6158,"Effective quantum yield in limiting light",1,NA,0.009022556,NA,0.005209175,3,0.8,0.010847021,0.166360074,0.668972973
"1363",1363,1379,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.5,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.621428571,"Effective quantum yield in limiting light","quantum yield","phys","dQ",NA,0.006766917,NA,0.003906881,3,20,NA,10,NA,0.6214,"Effective quantum yield in limiting light",1,NA,0.011278195,NA,0.006511469,3,0.8,0.009300238,0,0.666666667
"1364",1364,1380,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.610150376,"Effective quantum yield in limiting light","quantum yield","phys","dQ",NA,0.011278195,NA,0.006511469,3,20,NA,10,NA,0.6124,"Effective quantum yield in limiting light",1,NA,0.010150376,NA,0.005860322,3,0.8,0.010729115,0.168188262,0.669023941
"1365",1365,1381,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,8.17,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.575,"Effective quantum yield in saturating light","quantum yield","phys","dQ",NA,0.009090909,NA,0.005248639,3,20,NA,10,NA,0.5352,"Effective quantum yield in saturating light",1,NA,0.009090909,NA,0.005248639,3,0.8,0.009090909,-3.500000011,1.687500006
"1366",1366,1382,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.85,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.565909091,"Effective quantum yield in saturating light","quantum yield","phys","dQ",NA,0.009090909,NA,0.005248639,3,20,NA,10,NA,0.5466,"Effective quantum yield in saturating light",1,NA,0.005681818,NA,0.003280399,3,0.8,0.007580491,-2.038726246,1.013033726
"1367",1367,1383,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.5,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.603409091,"Effective quantum yield in saturating light","quantum yield","phys","dQ",NA,0.009090909,NA,0.005248639,3,20,NA,10,NA,0.5761,"Effective quantum yield in saturating light",1,NA,0.005681818,NA,0.003280399,3,0.8,0.007580491,-2.878201704,1.357003754
"1368",1368,1384,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.576136364,"Effective quantum yield in saturating light","quantum yield","phys","dQ",NA,0.009090909,NA,0.005248639,3,20,NA,10,NA,0.5489,"Effective quantum yield in saturating light",1,NA,0.004545455,NA,0.00262432,3,0.8,0.007186995,-3.035786598,1.434666689
"1369",1369,1385,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,8.17,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,9.669421488,"pg C cell-1","biom","biom","dSS",NA,1.983471074,NA,1.145157559,3,20,NA,10,NA,25.2066,"pg C cell-1",2,NA,5.123966942,NA,2.958323693,3,0.8,3.885176619,3.199275936,1.519613876
"1370",1370,1386,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.85,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,13.96694215,"pg C cell-1","biom","biom","dSS",NA,1.32231405,NA,0.763438372,3,20,NA,10,NA,26.5289,"pg C cell-1",2,NA,6.280991736,NA,3.626332269,3,0.8,4.538687675,2.214205404,1.075225464
"1371",1371,1387,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.5,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,10.16528926,"pg C cell-1","biom","biom","dSS",NA,4.628099174,NA,2.672034304,3,20,NA,10,NA,19.9174,"pg C cell-1",2,NA,3.305785124,NA,1.908595931,3,0.8,4.021661177,1.93990805,0.98027027
"1372",1372,1388,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,7.520661157,"pg C cell-1","biom","biom","dSS",NA,4.132231405,NA,2.385744914,3,20,NA,10,NA,15.6198,"pg C cell-1",2,NA,1.32231405,NA,0.763438372,3,0.8,3.067886148,2.111988037,1.038374456
"1373",1373,1389,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table S2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,8.17,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.34,"Chl a (pg cell)","cellular content","phys","Q",NA,0.01,NA,0.005773503,3,20,NA,10,NA,0.52,"Chl a (pg cell)",1,NA,0.01,NA,0.005773503,3,0.8,0.01,14.4,17.94666667
"1374",1374,1390,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table S2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.85,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.33,"Chl a (pg cell)","cellular content","phys","Q",NA,0.01,NA,0.005773503,3,20,NA,10,NA,0.5,"Chl a (pg cell)",1,NA,0,NA,0,3,0.8,0.007071068,19.23330445,31.49333333
"1375",1375,1391,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table S2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.5,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.34,"Chl a (pg cell)","cellular content","phys","Q",NA,0.01,NA,0.005773503,3,20,NA,10,NA,0.51,"Chl a (pg cell)",1,NA,0.01,NA,0.005773503,3,0.8,0.01,13.6,16.08
"1376",1376,1392,"866","Liu, NN; Beardall, J; Gao, KS",2017,"Elevated CO2 and associated seawater chemistry do not benefit a model diatom grown with increased availability of light","AQUATIC MICROBIAL ECOLOGY",1,NA,NA,"Table S2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.15,NA,"No","pCo2","light reduced","12",NA,NA,20,7.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.34,"Chl a (pg cell)","cellular content","phys","Q",NA,0.02,NA,0.011547005,3,20,NA,10,NA,0.46,"Chl a (pg cell)",1,NA,0.01,NA,0.005773503,3,0.8,0.015811388,6.071573108,3.738666667
"1377",1377,1393,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,14,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,8.181818182,"growth rate","biom","biom","dSS",NA,1.8,NA,0.367423461,24,70,NA,46.66666667,NA,5.2364,"growth rate",2,NA,1.636363636,NA,0.334021329,24,0.983606557,1.720128767,-1.684274143,0.112883119
"1378",1378,1394,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,14,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,9.272727273,"growth rate","biom","biom","dSS",NA,2.454545455,NA,0.501031993,24,70,NA,46.66666667,NA,7.2,"growth rate",2,NA,1.527272727,NA,0.31175324,24,0.983606557,2.044181422,-0.997342073,0.0936947
"1379",1379,1395,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,9.381818182,"growth rate","biom","biom","dSS",NA,1.690909091,NA,0.345155373,24,70,NA,46.66666667,NA,6.1636,"growth rate",2,NA,1.036363636,NA,0.211546841,24,0.983606557,1.402359287,-2.257213803,0.136406397
"1380",1380,1396,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,8.181818182,"growth rate","biom","biom","dSS",NA,1.8,NA,0.367423461,24,30,NA,20,NA,3.6545,"growth rate",2,NA,0.763636364,NA,0.15587662,24,0.983606557,1.382595475,-3.22079395,0.191390767
"1381",1381,1397,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,24,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,9.272727273,"growth rate","biom","biom","dSS",NA,2.454545455,NA,0.501031993,24,30,NA,20,NA,3.7636,"growth rate",2,NA,1.036363636,NA,0.211546841,24,0.983606557,1.883990841,-2.876223083,0.169506867
"1382",1382,1398,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,24,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,9.381818182,"growth rate","biom","biom","dSS",NA,1.690909091,NA,0.345155373,24,30,NA,20,NA,1.8545,"growth rate",2,NA,0.927272727,NA,0.189278753,24,0.983606557,1.363636364,-5.429508197,0.390412076
"1383",1383,1399,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,14,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,40.54794521,"production","productivity","phys","dQ",NA,9.315068493,NA,1.901430394,24,70,NA,46.66666667,NA,23.8356,"productivity g m^-3 day^-1",1,NA,7.397260274,NA,1.50995943,24,0.983606557,8.411003525,-1.954387026,0.123121132
"1384",1384,1400,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,14,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,47.67123288,"production","productivity","phys","dQ",NA,10.4109589,NA,2.125128087,24,70,NA,46.66666667,NA,33.9726,"productivity g m^-3 day^-1",1,NA,7.123287671,NA,1.454035007,24,0.983606557,8.919901696,-1.510561763,0.10710205
"1385",1385,1401,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,44.93150685,"production","productivity","phys","dQ",NA,8.219178082,NA,1.677732701,24,70,NA,46.66666667,NA,26.0274,"productivity g m^-3 day^-1",1,NA,5.479452055,NA,1.118488467,24,0.983606557,6.984958238,-2.662035408,0.157150339
"1386",1386,1402,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,40.54794521,"production","productivity","phys","dQ",NA,9.315068493,NA,1.901430394,24,30,NA,20,NA,14.2466,"productivity g m^-3 day^-1",1,NA,3.01369863,NA,0.615168657,24,0.983606557,6.922892476,-3.736906207,0.228796542
"1387",1387,1403,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,24,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,47.67123288,"production","productivity","phys","dQ",NA,10.4109589,NA,2.125128087,24,30,NA,20,NA,15.6164,"productivity g m^-3 day^-1",1,NA,4.383561644,NA,0.894790774,24,0.983606557,7.987605335,-3.94727891,0.245635529
"1388",1388,1404,"870","Patarra, RF; Carreiro, AS; Lloveras, AA; Abreu, MH; Buschmann, AH; Neto, AI",2017,"Effects of light, temperature and stocking density on Halopteris scoparia growth","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 3","spring","2014","Lab","coastal",37.833333,-25.5,NA,"Halopteris scoparia","macroalgae",22,"microcosm","culture flask",NA,NA,"No","temp","gradient","12",NA,NA,24,NA,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,44.93150685,"production","productivity","phys","dQ",NA,8.219178082,NA,1.677732701,24,30,NA,20,NA,7.1233,"productivity g m^-3 day^-1",1,NA,3.561643836,NA,0.727017504,24,0.983606557,6.334042752,-5.871196922,0.442405763
"1389",1389,1405,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade are",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,3,"growth rate","biom","biom","dSS",NA,2.75,NA,1.122682799,6,30,NA,16.66666667,NA,2.1875,"growth rate",2,NA,2.875,NA,1.173713835,6,0.923076923,2.813194359,-0.266600847,0.336294834
"1390",1390,1406,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade are",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,1.125,"growth rate","biom","biom","dSS",NA,2.9375,NA,1.199229353,6,30,NA,16.66666667,NA,0.8125,"growth rate",2,NA,1.5625,NA,0.637887954,6,0.923076923,2.352691278,-0.122609176,0.333959709
"1391",1391,1407,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade are",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,0.25,"growth rate","biom","biom","dSS",NA,4.8125,NA,1.964694898,6,30,NA,16.66666667,NA,0.1875,"growth rate",2,NA,1.4375,NA,0.586856918,6,0.923076923,3.551518161,-0.016244407,0.333344328
"1392",1392,1408,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade are",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,0.125,"growth rate","biom","biom","dSS",NA,3.25,NA,1.326806944,6,30,NA,16.66666667,NA,1.5,"growth rate",2,NA,0.8125,NA,0.331701736,6,0.923076923,2.368824207,0.535806231,0.345295347
"1393",1393,1409,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade length",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,-0.3,"growth rate","biom","biom","dSS",NA,-2.1,NA,-0.85732141,6,30,NA,16.66666667,NA,0.3,"growth rate",2,NA,2.2,NA,0.898146239,6,0.923076923,2.150581317,0.25753323,0.336096807
"1394",1394,1410,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade length",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,-0.9,"growth rate","biom","biom","dSS",NA,-2.6,NA,-1.061445555,6,30,NA,16.66666667,NA,0.7,"growth rate",2,NA,1.8,NA,0.734846923,6,0.923076923,2.236067977,0.66050008,0.351510848
"1395",1395,1411,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade length",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,-0.6,"growth rate","biom","biom","dSS",NA,-3.5,NA,-1.428869017,6,30,NA,16.66666667,NA,-0.4,"growth rate",2,NA,-1.7,NA,-0.694022094,6,0.923076923,2.751363298,0.067099603,0.333520932
"1396",1396,1412,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade length",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,-0.3,"growth rate","biom","biom","dSS",NA,-1.9,NA,-0.775671752,6,30,NA,16.66666667,NA,-0.4,"growth rate",2,NA,-2.1,NA,-0.85732141,6,0.923076923,2.002498439,-0.046096262,0.333421869
"1397",1397,1413,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on wet weight",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,5.428571429,"growth rate","biom","biom","dSS",NA,1.959183673,NA,0.799833385,6,30,NA,16.66666667,NA,4.2857,"growth rate",2,NA,2.93877551,NA,1.199750078,6,0.923076923,2.497478945,-0.422403983,0.340767714
"1398",1398,1414,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on wet weight",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,2.489795918,"growth rate","biom","biom","dSS",NA,0.979591837,NA,0.399916693,6,30,NA,16.66666667,NA,3.0612,"growth rate",2,NA,1.06122449,NA,0.433243084,6,0.923076923,1.021224164,0.516510034,0.344449276
"1399",1399,1415,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on wet weight",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,1.918367347,"growth rate","biom","biom","dSS",NA,3.183673469,NA,1.299729251,6,30,NA,16.66666667,NA,1.6735,"growth rate",2,NA,0.979591837,NA,0.399916693,6,0.923076923,2.35535315,-0.095976968,0.333717149
"1400",1400,1416,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on wet weight",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,1.673469388,"growth rate","biom","biom","dSS",NA,1.632653061,NA,0.666527821,6,30,NA,16.66666667,NA,2.1633,"growth rate",2,NA,0.816326531,NA,0.333263911,6,0.923076923,1.290725576,0.350283064,0.338445759
"1401",1401,1417,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade width",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,2.666666667,"growth rate","biom","biom","dSS",NA,1.583333333,NA,0.646393127,6,30,NA,16.66666667,NA,1.5833,"growth rate",2,NA,1.833333333,NA,0.748455199,6,0.923076923,1.712900399,-0.583805106,0.347534517
"1402",1402,1418,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade width",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,23,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,0.916666667,"growth rate","biom","biom","dSS",NA,1.083333333,NA,0.442268981,6,30,NA,16.66666667,NA,-0.25,"growth rate",2,NA,-0.541666667,NA,-0.221134491,6,0.923076923,0.8564502,-1.257426383,0.39921338
"1403",1403,1419,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade width",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,140.41,NA,NA,NA,2,180,NA,100,NA,0.333333333,"growth rate","biom","biom","dSS",NA,0.916666667,NA,0.3742276,6,30,NA,16.66666667,NA,-0.4167,"growth rate",2,NA,-0.333333333,NA,-0.136082763,6,0.923076923,0.689706057,-1.003772094,0.375314934
"1404",1404,1420,"884","Endo, H; Suehiro, K; Gao, X; Agatsuma, Y",2017,"Interactive effects of elevated summer temperature, nutrient availability, and irradiance on growth and chemical compositions of juvenile kelp, Eisenia bicyclis","PHYCOLOGICAL RESEARCH",1,"relative growth rate based on blade width",NA,"Fig. 1","summer",NA,"Lab","coastal",38.39031,141.26056,"Shizugawa Bay","Eisenia bicyclis","kelp",9,"microcosm","culture flask",0.5,NA,"No","temp_nut","light reduced","12",NA,NA,26,NA,NA,NA,0.16,3.22,NA,NA,NA,2,180,NA,100,NA,1.083333333,"growth rate","biom","biom","dSS",NA,1.916666667,NA,0.78247589,6,30,NA,16.66666667,NA,0.1667,"growth rate",2,NA,0.916666667,NA,0.3742276,6,0.923076923,1.502313031,-0.563234045,0.346551358
"1405",1405,1421,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.94,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,1.265096443,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.2744,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1406",1406,1422,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.978947368,NA,NA,NA,NA,1,168,NA,100,NA,1.375012116,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.4192,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1407",1407,1423,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.042105263,NA,NA,NA,NA,1,258,NA,100,NA,1.765241834,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.8094,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1408",1408,1424,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.99,NA,NA,0.768421053,NA,NA,NA,NA,1,312,NA,100,NA,2.471261025,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,2.6209,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1409",1409,1425,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.610526316,NA,NA,NA,NA,1,306,NA,100,NA,3.844334593,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,4.064,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1410",1410,1426,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.6,NA,NA,NA,NA,1,270,NA,100,NA,4.234758166,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,3.7524,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1411",1411,1427,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.389473684,NA,NA,NA,NA,1,304,NA,100,NA,2.975671222,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,3.7569,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1412",1412,1428,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.347368421,NA,NA,NA,NA,1,304,NA,100,NA,3.436464088,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,3.5506,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1413",1413,1429,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.22,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,3.511098187,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,3.2746,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1414",1414,1430,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.79,NA,NA,0.989473684,NA,NA,NA,NA,1,146,NA,100,NA,1.265484152,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.3095,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1415",1415,1431,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.968421053,NA,NA,NA,NA,1,168,NA,100,NA,1.269748958,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.4543,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1416",1416,1432,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.084210526,NA,NA,NA,NA,1,258,NA,100,NA,1.870504992,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.6693,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1417",1417,1433,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.84,NA,NA,0.821052632,NA,NA,NA,NA,1,312,NA,100,NA,2.681981196,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,2.3051,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1418",1418,1434,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.673684211,NA,NA,NA,NA,1,306,NA,100,NA,4.124842493,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,3.6429,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1419",1419,1435,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.631578947,NA,NA,NA,NA,1,270,NA,100,NA,4.340021324,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,4.279,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1420",1420,1436,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.431578947,NA,NA,NA,NA,1,304,NA,100,NA,4.169041388,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,4.5286,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1421",1421,1437,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.378947368,NA,NA,NA,NA,1,304,NA,100,NA,3.015411457,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,3.2699,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1422",1422,1438,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.11,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,3.230396433,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,3.2042,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1423",1423,1439,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,0.957894737,NA,NA,NA,NA,1,146,NA,100,NA,1.265484152,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.2746,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1424",1424,1440,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.947368421,NA,NA,NA,NA,1,168,NA,100,NA,1.40990598,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.349,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1425",1425,1441,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.021052632,NA,NA,NA,NA,1,258,NA,100,NA,1.800329553,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.7393,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1426",1426,1442,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.7,NA,NA,0.768421053,NA,NA,NA,NA,1,312,NA,100,NA,2.401279442,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,2.5507,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1427",1427,1443,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.578947368,NA,NA,NA,NA,1,306,NA,100,NA,3.774159155,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,4.3796,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1428",1428,1444,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.578947368,NA,NA,NA,NA,1,270,NA,100,NA,4.445090627,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,4.8051,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1429",1429,1445,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.410526316,NA,NA,NA,NA,1,304,NA,100,NA,2.695163323,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,4.1778,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1430",1430,1446,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.336842105,NA,NA,NA,NA,1,304,NA,100,NA,3.822429001,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,3.7612,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1431",1431,1447,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.06,NA,NA,0.315789474,NA,NA,NA,NA,1,211,NA,100,NA,3.510904333,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,3.4849,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1432",1432,1448,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.46,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,1.195114859,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.2393,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1433",1433,1449,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.978947368,NA,NA,NA,NA,1,168,NA,100,NA,1.339730542,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.349,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1434",1434,1450,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.073684211,NA,NA,NA,NA,1,258,NA,100,NA,1.274013764,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.4938,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1435",1435,1451,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.49,NA,NA,0.873684211,NA,NA,NA,NA,1,312,NA,100,NA,1.945139091,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,1.9543,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1436",1436,1452,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.789473684,NA,NA,NA,NA,1,306,NA,100,NA,2.826790734,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,2.6954,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1437",1437,1453,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.652631579,NA,NA,NA,NA,1,270,NA,100,NA,4.445284482,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,4.2086,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1438",1438,1454,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.410526316,NA,NA,NA,NA,1,304,NA,100,NA,3.467093147,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,4.4585,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1439",1439,1455,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.347368421,NA,NA,NA,NA,1,304,NA,100,NA,4.313657071,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,4.2173,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1440",1440,1456,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.83,NA,NA,0.336842105,NA,NA,NA,NA,1,211,NA,100,NA,3.756712223,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,3.7305,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1441",1441,1457,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,1.265096443,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.3097,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1442",1442,1458,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.957894737,NA,NA,NA,NA,1,168,NA,100,NA,1.41029369,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.3839,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1443",1443,1459,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.052631579,NA,NA,NA,NA,1,258,NA,100,NA,1.379276922,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.4935,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1444",1444,1460,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.36,NA,NA,0.852631579,NA,NA,NA,NA,1,312,NA,100,NA,1.594261898,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,1.8841,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1445",1445,1461,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.789473684,NA,NA,NA,NA,1,306,NA,100,NA,2.089948628,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,2.3094,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1446",1446,1462,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.705263158,NA,NA,NA,NA,1,270,NA,100,NA,2.831249394,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,3.4016,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1447",1447,1463,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.442105263,NA,NA,NA,NA,1,304,NA,100,NA,3.712901037,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,4.0376,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1448",1448,1464,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.4,NA,NA,NA,NA,1,304,NA,100,NA,3.436270234,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,3.1647,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1449",1449,1465,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,3.230008723,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,3.5551,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1450",1450,1466,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.16,NA,NA,0.968421053,NA,NA,NA,NA,1,146,NA,100,NA,1.335465736,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.2746,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1451",1451,1467,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.968421053,NA,NA,NA,NA,1,168,NA,100,NA,1.304642823,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.3139,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1452",1452,1468,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.073684211,NA,NA,NA,NA,1,258,NA,100,NA,1.519627799,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.3535,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1453",1453,1469,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.17,NA,NA,0.905263158,NA,NA,NA,NA,1,312,NA,100,NA,1.48899874,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,1.5683,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1454",1454,1470,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.852631579,NA,NA,NA,NA,1,306,NA,100,NA,1.774159155,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,1.9236,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1455",1455,1471,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.778947368,NA,NA,NA,NA,1,270,NA,100,NA,2.234758166,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,2.5946,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1456",1456,1472,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.526315789,NA,NA,NA,NA,1,304,NA,100,NA,3.362023844,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,3.0902,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1457",1457,1473,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.463157895,NA,NA,NA,NA,1,304,NA,100,NA,3.752253562,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,3.4103,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1458",1458,1474,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","community","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.33,NA,NA,0.421052632,NA,NA,NA,NA,1,211,NA,100,NA,3.37074731,"chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,3.3446,"chl a (µg L-1)",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1459",1459,1475,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.94,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,0.72484639,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.1233,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1460",1460,1476,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.94,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,1.101190476,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.1425,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1461",1461,1477,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.978947368,NA,NA,NA,NA,1,168,NA,100,NA,1.477534562,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.6964,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1462",1462,1478,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.042105263,NA,NA,NA,NA,1,258,NA,100,NA,2.391513057,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,2.9675,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1463",1463,1479,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.99,NA,NA,0.768421053,NA,NA,NA,NA,1,312,NA,100,NA,5.090245776,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,4.7725,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1464",1464,1480,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.610526316,NA,NA,NA,NA,1,306,NA,100,NA,5.823732719,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,7.1141,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1465",1465,1481,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.6,NA,NA,NA,NA,1,270,NA,100,NA,7.092933948,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,8.7414,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1466",1466,1482,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.389473684,NA,NA,NA,NA,1,304,NA,100,NA,11.04070661,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,9.2963,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1467",1467,1483,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.347368421,NA,NA,NA,NA,1,304,NA,100,NA,11.9546851,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,14.6726,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1468",1468,1484,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.22,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,10.36674347,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,8.6204,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1469",1469,1485,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.79,NA,NA,0.989473684,NA,NA,NA,NA,1,146,NA,100,NA,0.723886329,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.4795,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1470",1470,1486,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.79,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.922619048,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.5006,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1471",1471,1487,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.968421053,NA,NA,NA,NA,1,168,NA,100,NA,2.014208909,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.5207,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1472",1472,1488,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.084210526,NA,NA,NA,NA,1,258,NA,100,NA,2.926267281,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,2.2533,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1473",1473,1489,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.84,NA,NA,0.821052632,NA,NA,NA,NA,1,312,NA,100,NA,6.339285714,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,4.2368,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1474",1474,1490,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.673684211,NA,NA,NA,NA,1,306,NA,100,NA,7.252304147,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,6.5783,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1475",1475,1491,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.631578947,NA,NA,NA,NA,1,270,NA,100,NA,9.591973886,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,9.6333,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1476",1476,1492,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.431578947,NA,NA,NA,NA,1,304,NA,100,NA,16.75595238,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,13.582,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1477",1477,1493,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.378947368,NA,NA,NA,NA,1,304,NA,100,NA,11.41801075,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,14.1369,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1478",1478,1494,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.11,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,11.43817204,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,10.049,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1479",1479,1495,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,0.957894737,NA,NA,NA,NA,1,146,NA,100,NA,0.903417819,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.1252,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1480",1480,1496,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,1.278801843,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.9649,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1481",1481,1497,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.947368421,NA,NA,NA,NA,1,168,NA,100,NA,1.658026114,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.3412,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1482",1482,1498,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.021052632,NA,NA,NA,NA,1,258,NA,100,NA,2.211021505,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,2.6104,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1483",1483,1499,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.7,NA,NA,0.768421053,NA,NA,NA,NA,1,312,NA,100,NA,4.909754224,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,5.6653,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1484",1484,1500,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.578947368,NA,NA,NA,NA,1,306,NA,100,NA,7.609447005,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,6.2212,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1485",1485,1501,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.578947368,NA,NA,NA,NA,1,270,NA,100,NA,9.235791091,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,13.7404,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1486",1486,1502,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.410526316,NA,NA,NA,NA,1,304,NA,100,NA,14.07642089,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,8.4025,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1487",1487,1503,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.336842105,NA,NA,NA,NA,1,304,NA,100,NA,14.81182796,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,13.245,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1488",1488,1504,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.06,NA,NA,0.315789474,NA,NA,NA,NA,1,211,NA,100,NA,15.01056068,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,12.0132,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1489",1489,1505,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.46,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,0.72484639,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.9457,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1490",1490,1506,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.46,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.743087558,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.1425,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1491",1491,1507,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.978947368,NA,NA,NA,NA,1,168,NA,100,NA,1.299923195,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,1.1617,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1492",1492,1508,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.073684211,NA,NA,NA,NA,1,258,NA,100,NA,1.318164363,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.8961,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1493",1493,1509,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.49,NA,NA,0.873684211,NA,NA,NA,NA,1,312,NA,100,NA,2.588325653,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,2.9868,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1494",1494,1510,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.789473684,NA,NA,NA,NA,1,306,NA,100,NA,4.39516129,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,3.5417,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1495",1495,1511,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.652631579,NA,NA,NA,NA,1,270,NA,100,NA,5.843894009,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,6.4199,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1496",1496,1512,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.410526316,NA,NA,NA,NA,1,304,NA,100,NA,11.93452381,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,10.5453,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1497",1497,1513,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.347368421,NA,NA,NA,NA,1,304,NA,100,NA,14.8108679,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,18.6012,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1498",1498,1514,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.83,NA,NA,0.336842105,NA,NA,NA,NA,1,211,NA,100,NA,14.83102919,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,12.7275,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1499",1499,1515,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,0.723886329,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.3009,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1500",1500,1516,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,1.102150538,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.8568,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1501",1501,1517,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.957894737,NA,NA,NA,NA,1,168,NA,100,NA,1.477534562,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,2.0536,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1502",1502,1518,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.052631579,NA,NA,NA,NA,1,258,NA,100,NA,1.320084485,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.5399,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1503",1503,1519,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.36,NA,NA,0.852631579,NA,NA,NA,NA,1,312,NA,100,NA,1.696428571,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,2.8082,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1504",1504,1520,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.789473684,NA,NA,NA,NA,1,306,NA,100,NA,3.680875576,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,3.7222,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1505",1505,1521,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.705263158,NA,NA,NA,NA,1,270,NA,100,NA,3.520545315,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,6.2394,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1506",1506,1522,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.442105263,NA,NA,NA,NA,1,304,NA,100,NA,10.68452381,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,9.4739,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1507",1507,1523,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.4,NA,NA,NA,NA,1,304,NA,100,NA,7.310867896,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,12.3512,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1508",1508,1524,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,13.22292627,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,12.549,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1509",1509,1525,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,0.968421053,NA,NA,NA,NA,1,146,NA,100,NA,0.72484639,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.3018,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1510",1510,1526,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,1.100230415,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,1.1425,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1511",1511,1527,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.968421053,NA,NA,NA,NA,1,168,NA,100,NA,1.298963134,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,0.9841,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1512",1512,1528,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.073684211,NA,NA,NA,NA,1,258,NA,100,NA,0.7843702,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,1.3604,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1513",1513,1529,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.17,NA,NA,0.905263158,NA,NA,NA,NA,1,312,NA,100,NA,1.160714286,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,1.9163,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1514",1514,1530,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.852631579,NA,NA,NA,NA,1,306,NA,100,NA,2.609447005,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,2.8283,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1515",1515,1531,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.778947368,NA,NA,NA,NA,1,270,NA,100,NA,3.701036866,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,4.8118,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1516",1516,1532,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.526315789,NA,NA,NA,NA,1,304,NA,100,NA,10.14880952,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,10.5463,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1517",1517,1533,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.463157895,NA,NA,NA,NA,1,304,NA,100,NA,8.383256528,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,13.244,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1518",1518,1534,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","Nano-phytoplankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.33,NA,NA,0.421052632,NA,NA,NA,NA,1,211,NA,100,NA,9.831029186,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,10.9418,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1519",1519,1535,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.94,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,-0.001758312,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0016,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1520",1520,1536,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.94,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.00219789,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0011,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1521",1521,1537,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.978947368,NA,NA,NA,NA,1,168,NA,100,NA,0.006106138,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,0.005,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1522",1522,1538,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.042105263,NA,NA,NA,NA,1,258,NA,100,NA,0.018861893,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,0.0089,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1523",1523,1539,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.99,NA,NA,0.768421053,NA,NA,NA,NA,1,312,NA,100,NA,0.027157928,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,0.035,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1524",1524,1540,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.610526316,NA,NA,NA,NA,1,306,NA,100,NA,0.048737212,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,0.0477,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1525",1525,1541,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.6,NA,NA,NA,NA,1,270,NA,100,NA,0.085757673,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,0.1266,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1526",1526,1542,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.389473684,NA,NA,NA,NA,1,304,NA,100,NA,0.136013427,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,0.1349,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1527",1527,1543,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.347368421,NA,NA,NA,NA,1,304,NA,100,NA,0.135485934,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,0.0683,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1528",1528,1544,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"1L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.22,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,0.086476982,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,0.0281,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1529",1529,1545,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.79,NA,NA,0.989473684,NA,NA,NA,NA,1,146,NA,100,NA,0.002701407,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0016,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1530",1530,1546,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.79,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,-0.002213875,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0011,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1531",1531,1547,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.968421053,NA,NA,NA,NA,1,168,NA,100,NA,0.006082161,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,6e-04,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1532",1532,1548,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.084210526,NA,NA,NA,NA,1,258,NA,100,NA,0.014426151,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,0.0046,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1533",1533,1549,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.84,NA,NA,0.821052632,NA,NA,NA,NA,1,312,NA,100,NA,0.027157928,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,0.0261,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1534",1534,1550,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.673684211,NA,NA,NA,NA,1,306,NA,100,NA,0.061972506,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,0.0565,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1535",1535,1551,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.631578947,NA,NA,NA,NA,1,270,NA,100,NA,0.11445812,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,0.1354,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1536",1536,1552,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.431578947,NA,NA,NA,NA,1,304,NA,100,NA,0.158072251,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,0.2187,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1537",1537,1553,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.378947368,NA,NA,NA,NA,1,304,NA,100,NA,0.157568734,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,0.183,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1538",1538,1554,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"2L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.11,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,0.099736253,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,0.1825,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1539",1539,1555,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,0.957894737,NA,NA,NA,NA,1,146,NA,100,NA,0.002653453,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0016,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1540",1540,1556,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.00219789,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0055,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1541",1541,1557,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.947368421,NA,NA,NA,NA,1,168,NA,100,NA,0.00171835,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,6e-04,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1542",1542,1558,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.021052632,NA,NA,NA,NA,1,258,NA,100,NA,0.005626598,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,0.009,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1543",1543,1559,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.7,NA,NA,0.768421053,NA,NA,NA,NA,1,312,NA,100,NA,0.036005435,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,0.0261,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1544",1544,1560,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.578947368,NA,NA,NA,NA,1,306,NA,100,NA,0.061972506,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,0.0389,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1545",1545,1561,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.578947368,NA,NA,NA,NA,1,270,NA,100,NA,0.118845908,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,0.1354,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1546",1546,1562,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.410526316,NA,NA,NA,NA,1,304,NA,100,NA,0.153636509,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,0.1481,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1547",1547,1563,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.336842105,NA,NA,NA,NA,1,304,NA,100,NA,0.175191816,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,0.1345,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1548",1548,1564,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"3L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,8.06,NA,NA,0.315789474,NA,NA,NA,NA,1,211,NA,100,NA,0.11294757,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,0.1031,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1549",1549,1565,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.46,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,0.007089194,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,-0.0028,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1550",1550,1566,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.46,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.006657609,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0011,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1551",1551,1567,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.978947368,NA,NA,NA,NA,1,168,NA,100,NA,0.006130115,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,0.005,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1552",1552,1568,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.073684211,NA,NA,NA,NA,1,258,NA,100,NA,0.01006234,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,0.009,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1553",1553,1569,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.49,NA,NA,0.873684211,NA,NA,NA,NA,1,312,NA,100,NA,0.036029412,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,0.0437,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1554",1554,1570,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.789473684,NA,NA,NA,NA,1,306,NA,100,NA,0.061996483,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,0.0653,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1555",1555,1571,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.652631579,NA,NA,NA,NA,1,270,NA,100,NA,0.118821931,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,0.1707,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1556",1556,1572,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.410526316,NA,NA,NA,NA,1,304,NA,100,NA,0.237484015,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,0.232,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1557",1557,1573,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.347368421,NA,NA,NA,NA,1,304,NA,100,NA,0.285485934,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,0.2977,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1558",1558,1574,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"4L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.83,NA,NA,0.336842105,NA,NA,NA,NA,1,211,NA,100,NA,0.22767743,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,0.2884,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1559",1559,1575,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,0.978947368,NA,NA,NA,NA,1,146,NA,100,NA,0.00267743,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0016,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1560",1560,1576,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.006585678,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0011,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1561",1561,1577,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.957894737,NA,NA,NA,NA,1,168,NA,100,NA,0.006082161,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,0.005,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1562",1562,1578,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.052631579,NA,NA,NA,NA,1,258,NA,100,NA,0.014426151,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,0.009,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1563",1563,1579,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.36,NA,NA,0.852631579,NA,NA,NA,NA,1,312,NA,100,NA,0.03159367,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,0.0305,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1564",1564,1580,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.789473684,NA,NA,NA,NA,1,306,NA,100,NA,0.061972506,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,0.0521,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1565",1565,1581,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.705263158,NA,NA,NA,NA,1,270,NA,100,NA,0.101198849,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,0.131,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1566",1566,1582,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.442105263,NA,NA,NA,NA,1,304,NA,100,NA,0.202165921,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,0.2188,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1567",1567,1583,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.4,NA,NA,NA,NA,1,304,NA,100,NA,0.298745205,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,0.2712,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1568",1568,1584,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.65,NA,NA,0.357894737,NA,NA,NA,NA,1,211,NA,100,NA,0.315912724,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,0.2751,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1569",1569,1585,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,0.968421053,NA,NA,NA,NA,1,146,NA,100,NA,0.007089194,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.006,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1570",1570,1586,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"5L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",1.5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.34,NA,NA,NA,NA,NA,NA,NA,1,146,NA,100,NA,0.006585678,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,61,NA,41.78082192,NA,0.0011,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1571",1571,1587,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",2,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.968421053,NA,NA,NA,NA,1,168,NA,100,NA,0.010517903,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,70,NA,41.66666667,NA,0.0095,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1572",1572,1588,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",3,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,1.073684211,NA,NA,NA,NA,1,258,NA,100,NA,0.005626598,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,109,NA,42.24806202,NA,0.0045,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1573",1573,1589,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",4,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.17,NA,NA,0.905263158,NA,NA,NA,NA,1,312,NA,100,NA,0.022794118,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,131,NA,41.98717949,NA,0.0261,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1574",1574,1590,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",5,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.852631579,NA,NA,NA,NA,1,306,NA,100,NA,0.044349425,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,129,NA,42.15686275,NA,0.0388,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1575",1575,1591,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",6,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.778947368,NA,NA,NA,NA,1,270,NA,100,NA,0.079140026,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,124,NA,45.92592593,NA,0.1089,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1576",1576,1592,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",7,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.526315789,NA,NA,NA,NA,1,304,NA,100,NA,0.131577685,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,113,NA,37.17105263,NA,0.1923,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1577",1577,1593,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",8,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,NA,NA,NA,0.463157895,NA,NA,NA,NA,1,304,NA,100,NA,0.21050991,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,128,NA,42.10526316,NA,0.2845,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1578",1578,1594,"896","Hussherr, R; Levasseur, M; Lizotte, M; Tremblay, JE; Mol, J; Thomas, H; Gosselin, M; Starr, M; Miller, LA; Jarnikova, T; Schuback, N; Mucci, A",2017,"Impact of ocean acidification on Arctic phytoplankton blooms and dimethyl sulfide concentration under simulated ice-free and under-ice conditions","BIOGEOSCIENCES",1,"6L",NA,"Fig 4","summer","2015","Field","arctic water",71.406217,-70.187817,"Baffin Bay","pico plankton","phytoplankton",9,"microcosm","culture flask",10,NA,"No","pH","light reduced",NA,272,NA,4.3,7.33,NA,NA,0.421052632,NA,NA,NA,NA,1,211,NA,100,NA,0.289418159,"cells mL-1","abundance","biom","SS",NA,NA,NA,NA,1,89,NA,42.18009479,NA,0.3899,"cells mL-1",2,NA,NA,NA,NA,1,4,NA,NA,NA
"1579",1579,1595,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,2,8.24,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,1.307692308,"growth rate","abundance","biom","dSS",NA,0.179487179,NA,0.073275334,6,38,NA,26.20689655,NA,5.5897,"growth rate",2,NA,0.717948718,NA,0.293101337,6,0.923076923,0.523290555,7.553476146,2.710625078
"1580",1580,1596,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,2,7.8,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,1.923076923,"growth rate","abundance","biom","dSS",NA,0.333333333,NA,0.136082763,6,38,NA,26.20689655,NA,7.2564,"growth rate",2,NA,0.974358974,NA,0.397780386,6,0.923076923,0.728178042,6.760814853,2.237859062
"1581",1581,1597,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,7,8.24,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,4.025641026,"growth rate","abundance","biom","dSS",NA,0.769230769,NA,0.314037147,6,38,NA,26.20689655,NA,4.3333,"growth rate",2,NA,0.794871795,NA,0.324505051,6,0.923076923,0.782156361,0.363129015,0.338827612
"1582",1582,1598,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,7,7.84,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,5.923076923,"growth rate","abundance","biom","dSS",NA,0.58974359,NA,0.240761812,6,38,NA,26.20689655,NA,5.7692,"growth rate",2,NA,0.487179487,NA,0.198890193,6,0.923076923,0.540898028,-0.262548257,0.336205483
"1583",1583,1599,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,2,8.24,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,12,"net PS","productivity","phys","dQ",NA,1.2,NA,0.489897949,6,38,NA,26.20689655,NA,2.2667,"net PS",1,NA,1.2,NA,0.489897949,6,0.923076923,1.2,-7.487179487,2.669077361
"1584",1584,1600,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,2,7.8,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,18.53333333,"net PS","productivity","phys","dQ",NA,4.933333333,NA,2.0140249,6,38,NA,26.20689655,NA,4.4,"net PS",1,NA,2.4,NA,0.979795897,6,0.923076923,3.87928974,-3.363026409,0.80458111
"1585",1585,1601,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,7,8.24,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,14.66666667,"net PS","productivity","phys","dQ",NA,2.266666667,NA,0.925362792,6,38,NA,26.20689655,NA,17.7333,"net PS",1,NA,2,NA,0.816496581,6,0.923076923,2.137495939,1.324338998,0.406411408
"1586",1586,1602,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,7,7.84,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,19.2,"net PS","productivity","phys","dQ",NA,2.8,NA,1.143095213,6,38,NA,26.20689655,NA,21.0667,"net PS",1,NA,2.266666667,NA,0.925362792,6,0.923076923,2.547329757,0.676424762,0.352397936
"1587",1587,1603,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 5",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,2,8.24,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,1.312997347,"chl a (mg g FW)","cellular content","phys","Q",NA,0.119363395,NA,0.048729902,6,38,NA,26.20689655,NA,0.382,"chl a (mg g FW)",2,NA,0.055702918,NA,0.022740621,6,0.923076923,0.093140848,-9.227062703,3.880778589
"1588",1588,1604,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 5",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,2,7.8,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,1.165782493,"chl a (mg g FW)","cellular content","phys","Q",NA,0.194960212,NA,0.079592173,6,38,NA,26.20689655,NA,0.5093,"chl a (mg g FW)",2,NA,0.071618037,NA,0.029237941,6,0.923076923,0.146864951,-4.126231427,1.042741074
"1589",1589,1605,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 5",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,7,8.24,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,1.364721485,"chl a (mg g FW)","cellular content","phys","Q",NA,0.103448276,NA,0.042232582,6,38,NA,26.20689655,NA,1.5239,"chl a (mg g FW)",2,NA,0.055702918,NA,0.022740621,6,0.923076923,0.083079362,1.76829468,0.46361942
"1590",1590,1606,"904","Iniguez, C; Heinrich, S; Harms, L; Gordillo, FJL",2017,"Increased temperature and CO2 alleviate photoinhibition in Desmarestia anceps: from transcriptomics to carbon utilization","JOURNAL OF EXPERIMENTAL BOTANY",1,NA,NA,"Fig. 5",NA,NA,"Lab","coastal",-62.2333333,-58.63333333,"arctic","Desmarestia anceps","macroalgae",13,"microcosm","culture flask",0.6,NA,"No","temp_pCO2","light reduced","18",NA,NA,7,7.84,NA,NA,NA,NA,NA,NA,NA,0,145,NA,100,NA,1.49204244,"chl a (mg g FW)","cellular content","phys","Q",NA,0.206896552,NA,0.084465164,6,38,NA,26.20689655,NA,1.4483,"chl a (mg g FW)",2,NA,0.075596817,NA,0.030862271,6,0.923076923,0.155757924,-0.259376328,0.336136503
"1591",1591,1607,"914","Meunier, CL; Liess, A; Andersson, A; Brugel, S; Paczkowska, J; Rahman, H; Skoglund, B; Rowe, OF",2017,"Allochthonous carbon is a major driver of the microbial food web - A mesocosm study simulating elevated terrestrial matter runoff","MARINE ENVIRONMENTAL RESEARCH",1,NA,NA,"Fig. 2","summer","2013","field","coastal",63.556889,19.798556,"Baltic Sea","total phytoplankton","phytoplankton",49,"microcosm","culture flask",1.2,NA,"Yes",NA,"shading screen","16",NA,NA,18,NA,NA,NA,NA,NA,211.2408759,1192.941176,182.5396825,3,NA,NA,100,194.4444444,694.4444444,"biomass","biom","biom","SS",37.03703704,189.8148148,21.3833433,109.5896344,3,NA,NA,NA,194.4444444,925.9259,"biomass",2,37.03703704,129.6296296,21.3833433,74.84170156,3,0.8,162.5323119,1.139374584,0.77484787
"1592",1592,1608,"914","Meunier, CL; Liess, A; Andersson, A; Brugel, S; Paczkowska, J; Rahman, H; Skoglund, B; Rowe, OF",2017,"Allochthonous carbon is a major driver of the microbial food web - A mesocosm study simulating elevated terrestrial matter runoff","MARINE ENVIRONMENTAL RESEARCH",1,NA,NA,"Fig. 2","summer","2013","field","coastal",63.556889,19.798556,"Baltic Sea","total phytoplankton","phytoplankton",49,"microcosm","culture flask",1.2,NA,"Yes","carbon","shading screen","16",NA,NA,18,NA,NA,NA,NA,NA,125.4014599,1094.117647,125.3968254,3,NA,NA,100,194.4444444,78.7037037,"biomass","biom","biom","SS",37.03703704,120.3703704,21.3833433,69.49586574,3,NA,NA,NA,194.4444444,439.8148,"biomass",2,37.03703704,78.7037037,21.3833433,45.43960452,3,0.8,101.6939011,2.840769071,1.339164076
"1593",1593,1609,"914","Meunier, CL; Liess, A; Andersson, A; Brugel, S; Paczkowska, J; Rahman, H; Skoglund, B; Rowe, OF",2017,"Allochthonous carbon is a major driver of the microbial food web - A mesocosm study simulating elevated terrestrial matter runoff","MARINE ENVIRONMENTAL RESEARCH",1,"group-level growth avialable",NA,"Table 3","summer","2013","field","coastal",63.556889,19.798556,"Baltic Sea","total phytoplankton","phytoplankton",49,"microcosm","culture flask",1.2,NA,"Yes",NA,"shading screen","16",NA,NA,18,NA,NA,NA,NA,NA,211.2408759,1192.941176,182.5396825,3,NA,NA,100,0.34,0.95,"growth rate","biom","biom","dSS",NA,NA,NA,NA,3,NA,NA,NA,0.34,0.98,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1594",1594,1610,"914","Meunier, CL; Liess, A; Andersson, A; Brugel, S; Paczkowska, J; Rahman, H; Skoglund, B; Rowe, OF",2017,"Allochthonous carbon is a major driver of the microbial food web - A mesocosm study simulating elevated terrestrial matter runoff","MARINE ENVIRONMENTAL RESEARCH",1,"no sd for growth",NA,"Table 3","summer","2013","field","coastal",63.556889,19.798556,"Baltic Sea","total phytoplankton","phytoplankton",49,"microcosm","culture flask",1.2,NA,"Yes","carbon","shading screen","16",NA,NA,18,NA,NA,NA,NA,NA,125.4014599,1094.117647,125.3968254,3,NA,NA,100,0.34,-0.25,"growth rate","biom","biom","dSS",NA,NA,NA,NA,3,NA,NA,NA,0.34,0.35,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1595",1595,1611,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,28,7.84,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.390410959,"growth rate","biom","biom","dSS",NA,0.020547945,NA,0.011863362,3,50,NA,25,NA,0.2753,"growth rate",2,NA,0.04109589,NA,0.023726723,3,0.8,0.032489154,-2.833400784,1.33568
"1596",1596,1612,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,28,7.73,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.316438356,"growth rate","biom","biom","dSS",NA,0.057534247,NA,0.033217413,3,50,NA,25,NA,0.1274,"growth rate",2,NA,0.024657534,NA,0.014236034,3,0.8,0.044261629,-3.416794222,1.63954023
"1597",1597,1613,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,20,8.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.38630137,"growth rate","biom","biom","dSS",NA,0.061643836,NA,0.035590085,3,50,NA,25,NA,0.3781,"growth rate",2,NA,0.053424658,NA,0.03084474,3,0.8,0.057680831,-0.11399528,0.667749577
"1598",1598,1614,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,20,8.09,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.184931507,"growth rate","biom","biom","dSS",NA,0.053424658,NA,0.03084474,3,50,NA,25,NA,0.1192,"growth rate",2,NA,0.094520548,NA,0.054571464,3,0.8,0.076773459,-0.685168291,0.705787966
"1599",1599,1615,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 2","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,28,7.84,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.058378378,"chl a (pg cell)","cellular content","phys","Q",NA,0.012162162,NA,0.007021828,3,50,NA,25,NA,0.0624,"chl a (pg cell)",1,NA,0.017027027,NA,0.009830559,3,0.8,0.014795909,0.21919865,0.670670671
"1600",1600,1616,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 2","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,28,7.73,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.095675676,"chl a (pg cell)","cellular content","phys","Q",NA,0.011351351,NA,0.006553706,3,50,NA,25,NA,0.0673,"chl a (pg cell)",1,NA,0.017837838,NA,0.01029868,3,0.8,0.014950613,-1.518513205,0.858823529
"1601",1601,1617,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 2","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,20,8.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.049459459,"chl a (pg cell)","cellular content","phys","Q",NA,0.006486486,NA,0.003744975,3,50,NA,25,NA,0.0576,"chl a (pg cell)",1,NA,0.011351351,NA,0.006553706,3,0.8,0.009244666,0.701646415,0.707692308
"1602",1602,1618,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,20,8.09,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.096486486,"chl a (pg cell)","cellular content","phys","Q",NA,0.012162162,NA,0.007021828,3,50,NA,25,NA,0.0722,"chl a (pg cell)",1,NA,0.017027027,NA,0.009830559,3,0.8,0.014795909,-1.315191898,0.810810811
"1603",1603,1619,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,28,7.84,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.361643836,"Fv/Fm","productivity","phys","dQ",NA,0.049315068,NA,0.028472068,3,50,NA,25,NA,0.4274,"Fv/Fm",1,NA,0.020547945,NA,0.011863362,3,0.8,0.037776938,1.392456431,0.828244576
"1604",1604,1620,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,28,7.73,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.447945205,"Fv/Fm","productivity","phys","dQ",NA,0.024657534,NA,0.014236034,3,50,NA,25,NA,0.3904,"Fv/Fm",1,NA,0.073972603,NA,0.042708102,3,0.8,0.055135923,-0.834798712,0.724740741
"1605",1605,1621,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,20,8.19,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.480821918,"Fv/Fm","productivity","phys","dQ",NA,0.061643836,NA,0.035590085,3,50,NA,25,NA,0.6164,"Fv/Fm",1,NA,0.04109589,NA,0.023726723,3,0.8,0.052387187,2.070986387,1.024082051
"1606",1606,1622,"917","Guanyong, O;  Hong, W; Ranran, S;  Wanchun, G",2017,"The dinoflagellate Akashiwo sanguinea will benefit from future climate change: The interactive effects of ocean acidification, warming and high irradiance on photophysiology and hemolytic activity ","HARMFUL ALGAE",1,NA,NA,"Fig. 1","spring","2016","Lab","coastal",28.3333333,121.3333333,"Dongtue Island","Akashiwo sanguinea","phytoplankton",7,"microcosm","culture flask",5,NA,"No","pCO2_temp","light reduced","12",NA,NA,20,8.09,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.468493151,"Fv/Fm","productivity","phys","dQ",NA,0.036986301,NA,0.021354051,3,50,NA,25,NA,0.5137,"Fv/Fm",1,NA,0.04109589,NA,0.023726723,3,0.8,0.039095132,0.925035463,0.737974217
"1607",1607,1623,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","color_light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,587.8016072,"total cell volume","abundance","biom","SS",NA,304.7125534,NA,175.9258747,3,250,NA,36.76470588,NA,587.8016,"total cell volume",2,NA,178.8806002,NA,103.2767627,3,0.8,249.8479631,1.27407e-14,0.666666667
"1608",1608,1624,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,4972.9385,"total cell volume","abundance","biom","SS",NA,1849.089654,NA,1067.57241,3,250,NA,36.76470588,NA,2371.3737,"total cell volume",2,NA,336.8984688,NA,194.5084216,3,0.8,1329.028428,-1.565994971,0.871028354
"1609",1609,1625,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,9097.44305,"total cell volume","abundance","biom","SS",NA,629.5984602,NA,363.4988405,3,250,NA,36.76470588,NA,4311.3709,"total cell volume",2,NA,4065.405515,NA,2347.162969,3,0.8,2908.944501,-1.316236088,0.811039787
"1610",1610,1626,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,23221.32044,"total cell volume","abundance","biom","SS",NA,12759.06232,NA,7366.448068,3,250,NA,36.76470588,NA,14251.0267,"total cell volume",2,NA,24344.63237,NA,14055.38005,3,0.8,19435.21027,-0.369238866,0.678028112
"1611",1611,1627,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,82579.068,"total cell volume","abundance","biom","SS",NA,34050.98772,NA,19659.34693,3,250,NA,36.76470588,NA,41246.2638,"total cell volume",2,NA,56564.04167,NA,32657.26469,3,0.8,46684.90428,-0.708285555,0.708472369
"1612",1612,1628,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,123378.2253,"total cell volume","abundance","biom","SS",NA,34557.43392,NA,19951.74377,3,250,NA,36.76470588,NA,104527.5495,"total cell volume",2,NA,41173.11698,NA,23771.31017,3,0.8,38009.48435,-0.396757306,0.679784697
"1613",1613,1629,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,359576.0504,"total cell volume","abundance","biom","SS",NA,226378.0504,NA,130699.4283,3,250,NA,36.76470588,NA,247873.8825,"total cell volume",2,NA,54656.66323,NA,31556.03923,3,0.8,164672.9676,-0.542661832,0.691206822
"1614",1614,1630,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,1119370.56,"total cell volume","abundance","biom","SS",NA,1076006.807,NA,621232.8195,3,250,NA,36.76470588,NA,628169.6116,"total cell volume",2,NA,78141.84345,NA,45115.21435,3,0.8,762855.424,-0.51511826,0.688778902
"1615",1615,1631,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",17,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,3981663.747,"total cell volume","abundance","biom","SS",NA,3805021.794,NA,2196830.357,3,250,NA,36.76470588,NA,1942949.6147,"total cell volume",2,NA,1461343.15,NA,843706.8612,3,0.8,2882161.919,-0.565884691,0.693352124
"1616",1616,1632,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",19,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,9503051.622,"total cell volume","abundance","biom","SS",NA,NA,NA,NA,3,250,NA,36.76470588,NA,4311370.8854,"total cell volume",2,NA,3007049.499,NA,1736120.838,3,0.8,NA,NA,NA
"1617",1617,1633,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,717.4129813,"total cell volume","abundance","biom","SS",NA,9502819.734,NA,5486455.532,3,250,NA,36.76470588,NA,717.413,"total cell volume",2,NA,129.611374,NA,74.83116169,3,0.8,6719508.275,1.21816e-19,0.666666667
"1618",1618,1634,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,6069.480912,"total cell volume","abundance","biom","SS",NA,361.6428476,NA,208.7945954,3,250,NA,36.76470588,NA,2894.2661,"total cell volume",2,NA,411.1852229,NA,237.3978991,3,0.8,387.2072034,-6.560239086,4.253061405
"1619",1619,1635,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,10389.90683,"total cell volume","abundance","biom","SS",NA,3958.330236,NA,2285.343027,3,250,NA,36.76470588,NA,4607.4596,"total cell volume",2,NA,2727.278543,NA,1574.595001,3,0.8,3399.001802,-1.360975379,0.821021165
"1620",1620,1636,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,26520.34804,"total cell volume","abundance","biom","SS",NA,6261.530529,NA,3615.096337,3,250,NA,36.76470588,NA,14251.0267,"total cell volume",2,NA,4027.15515,NA,2325.07911,3,0.8,5264.254134,-1.864548485,0.956378421
"1621",1621,1637,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,131427.2495,"total cell volume","abundance","biom","SS",NA,10830.86999,NA,6253.205705,3,250,NA,36.76470588,NA,44078.9021,"total cell volume",2,NA,22850.21793,NA,13192.57947,3,0.8,17880.71872,-3.908046368,1.939402201
"1622",1622,1638,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,171976.5721,"total cell volume","abundance","biom","SS",NA,122143.0298,NA,70519.31114,3,250,NA,36.76470588,NA,111706.1086,"total cell volume",2,NA,77911.59863,NA,44982.28244,3,0.8,102443.0011,-0.470665348,0.685127156
"1623",1623,1639,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,572418.7285,"total cell volume","abundance","biom","SS",NA,123587.4378,NA,71353.24047,3,250,NA,36.76470588,NA,302530.5457,"total cell volume",2,NA,245037.4909,NA,141472.4614,3,0.8,194058.2731,-1.112606759,0.769824483
"1624",1624,1640,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,1781955.923,"total cell volume","abundance","biom","SS",NA,993292.0397,NA,573477.4265,3,250,NA,36.76470588,NA,766682.2075,"total cell volume",2,NA,691692.7865,NA,399349.0165,3,0.8,855881.9974,-0.948984761,0.74171434
"1625",1625,1641,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",17,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,6772143.885,"total cell volume","abundance","biom","SS",NA,2500661.132,NA,1443757.378,3,250,NA,36.76470588,NA,2076384.0891,"total cell volume",2,NA,1940046.571,NA,1120086.41,3,0.8,2237977.524,-1.678572638,0.901467175
"1626",1626,1642,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",19,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,13246277.76,"total cell volume","abundance","biom","SS",NA,NA,NA,NA,3,250,NA,36.76470588,NA,4607459.6278,"total cell volume",2,NA,4441059.427,NA,2564046.856,3,0.8,NA,NA,NA
"1627",1627,1643,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,231.9447866,"total cell volume","abundance","biom","SS",NA,6771966.057,NA,3909796.426,3,250,NA,36.76470588,NA,587.8016,"total cell volume",2,NA,231.5334516,NA,133.6759006,3,0.8,4788503.124,5.94519e-05,0.666666667
"1628",1628,1644,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,2394.999329,"total cell volume","abundance","biom","SS",NA,13245722.26,NA,7647421.311,3,250,NA,36.76470588,NA,1818.09,"total cell volume",2,NA,1956.963178,NA,1129.853218,3,0.8,9366140.132,-4.92762e-05,0.666666667
"1629",1629,1645,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,5717.570633,"total cell volume","abundance","biom","SS",NA,1497.794977,NA,864.7523333,3,250,NA,36.76470588,NA,8952.0619,"total cell volume",2,NA,614.7939536,NA,354.9514546,3,0.8,1144.849641,2.260203374,1.092376608
"1630",1630,1646,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,17798.9614,"total cell volume","abundance","biom","SS",NA,4003.494923,NA,2311.418872,3,250,NA,36.76470588,NA,36115.3899,"total cell volume",2,NA,22780.17557,NA,13152.1405,3,0.8,16354.88261,0.895949126,0.733560403
"1631",1631,1647,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,82558.60426,"total cell volume","abundance","biom","SS",NA,3976.648781,NA,2295.919244,3,250,NA,36.76470588,NA,91524.7311,"total cell volume",2,NA,65615.08156,NA,37882.885,3,0.8,46482.00008,0.15431568,0.668651111
"1632",1632,1648,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,225092.3795,"total cell volume","abundance","biom","SS",NA,16254.06539,NA,9384.289026,3,250,NA,36.76470588,NA,127576.0733,"total cell volume",2,NA,88980.41423,NA,51372.86611,3,0.8,63959.7872,-1.219720208,0.790643115
"1633",1633,1649,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,360736.437,"total cell volume","abundance","biom","SS",NA,55507.18774,NA,32047.08978,3,250,NA,36.76470588,NA,231944.7866,"total cell volume",2,NA,151805.3742,NA,87644.87365,3,0.8,114293.3058,-0.901481671,0.7343891
"1634",1634,1650,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,388098.807,"total cell volume","abundance","biom","SS",NA,825984.8203,NA,476882.5584,3,250,NA,36.76470588,NA,481606.4645,"total cell volume",2,NA,362228.8003,NA,209132.8954,3,0.8,637754.1169,0.117296187,0.6678132
"1635",1635,1651,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",17,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,53439.58642,"total cell volume","abundance","biom","SS",NA,2514226.956,NA,1451589.61,3,250,NA,36.76470588,NA,421696.5034,"total cell volume",2,NA,204657.1627,NA,118158.868,3,0.8,1783707.058,0.165164752,0.66893995
"1636",1636,1652,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",19,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,NA,"total cell volume","abundance","biom","SS",NA,NA,NA,NA,3,250,NA,36.76470588,NA,1068676.2402,"total cell volume",2,NA,785587.1863,NA,453558.9735,3,0.8,NA,NA,NA
"1637",1637,1653,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,883.232241,"total cell volume","abundance","biom","SS",NA,109.8706372,NA,63.43384197,3,250,NA,36.76470588,NA,819.3351,"total cell volume",2,NA,101.9220776,NA,58.84473894,3,0.8,105.9709083,-0.482375272,0.686057159
"1638",1638,1654,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,5360.761227,"total cell volume","abundance","biom","SS",NA,1.328767791,NA,0.767164442,3,250,NA,36.76470588,NA,2708.2722,"total cell volume",2,NA,2215.610457,NA,1279.183294,3,0.8,1566.673461,-1.354456622,0.819546062
"1639",1639,1655,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,26579.56894,"total cell volume","abundance","biom","SS",NA,7511.041146,NA,4336.501628,3,250,NA,36.76470588,NA,18587.9189,"total cell volume",2,NA,3358.185276,NA,1938.849173,3,0.8,5817.780825,-1.098927618,0.767303492
"1640",1640,1656,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,100987.941,"total cell volume","abundance","biom","SS",NA,6935.472092,NA,4004.196679,3,250,NA,36.76470588,NA,70170.3829,"total cell volume",2,NA,4819.038066,NA,2782.272925,3,0.8,5971.762764,-4.128437031,2.08699936
"1641",1641,1657,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,294321.343,"total cell volume","abundance","biom","SS",NA,206394.1015,NA,119161.69,3,250,NA,36.76470588,NA,190040.4954,"total cell volume",2,NA,93048.55847,NA,53721.61028,3,0.8,160088.3496,-0.521116486,0.689296866
"1642",1642,1658,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,1118261.417,"total cell volume","abundance","biom","SS",NA,2118284.722,NA,1222992.254,3,250,NA,36.76470588,NA,819335.0589,"total cell volume",2,NA,322733.8474,NA,186330.4737,3,0.8,1515138.162,-0.157834508,0.668742644
"1643",1643,1659,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,5186937.581,"total cell volume","abundance","biom","SS",NA,9825440.152,NA,5672720.516,3,250,NA,36.76470588,NA,2218982.3415,"total cell volume",2,NA,315248.3943,NA,182008.7453,3,0.8,6951210.532,-0.341575641,0.676389493
"1644",1644,1660,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,19712433.49,"total cell volume","abundance","biom","SS",NA,13823428.35,NA,7980960.081,3,250,NA,36.76470588,NA,6009608.1309,"total cell volume",2,NA,4214263.422,NA,2433106.121,3,0.8,10218786.32,-1.072755604,0.762567049
"1645",1645,1661,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",17,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,47059399.76,"total cell volume","abundance","biom","SS",NA,40180686.98,NA,23198330.45,3,250,NA,36.76470588,NA,17393405.2362,"total cell volume",2,NA,44048056.38,NA,25431157.21,3,0.8,42158740.95,-0.562938909,0.693075018
"1646",1646,1662,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",19,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,92025127.83,"total cell volume","abundance","biom","SS",NA,NA,NA,NA,3,250,NA,36.76470588,NA,33794510.0022,"total cell volume",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1647",1647,1663,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,1078.253832,"total cell volume","abundance","biom","SS",NA,92024534.91,NA,53130390,3,250,NA,36.76470588,NA,1000,"total cell volume",2,NA,33793959.97,NA,19510951.89,3,0.8,69320079.18,-9.03101e-07,0.666666667
"1648",1648,1664,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,6123.876256,"total cell volume","abundance","biom","SS",NA,2290.048157,NA,1322.15992,3,250,NA,36.76470588,NA,4034.3097,"total cell volume",2,NA,0,NA,0,3,0.8,1619.308581,-1.032325334,0.755474633
"1649",1649,1665,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,30348.17685,"total cell volume","abundance","biom","SS",NA,2469.489918,NA,1425.760669,3,250,NA,36.76470588,NA,21228.6842,"total cell volume",2,NA,1957.925577,NA,1130.408859,3,0.8,2228.435889,-3.273863134,1.559848319
"1650",1650,1666,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,107923.4131,"total cell volume","abundance","biom","SS",NA,42119.84114,NA,24317.90162,3,250,NA,36.76470588,NA,85643.0859,"total cell volume",2,NA,11004.81267,NA,6353.631557,3,0.8,30783.00602,-0.579029278,0.694606242
"1651",1651,1667,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,359219.7598,"total cell volume","abundance","biom","SS",NA,89608.46755,NA,51735.47286,3,250,NA,36.76470588,NA,217039.3407,"total cell volume",2,NA,59733.43642,NA,34487.1156,3,0.8,76150.38044,-1.49368046,0.85259011
"1652",1652,1668,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,1364840.19,"total cell volume","abundance","biom","SS",NA,179342.1678,NA,103543.2488,3,250,NA,36.76470588,NA,1142068.9063,"total cell volume",2,NA,119229.0352,NA,68836.91558,3,0.8,152281.2792,-1.170314748,0.780803051
"1653",1653,1669,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,4851204.675,"total cell volume","abundance","biom","SS",NA,3823383.074,NA,2207431.247,3,250,NA,36.76470588,NA,3093033.4402,"total cell volume",2,NA,796558.1768,NA,459893.0778,3,0.8,2761590.398,-0.509321364,0.688284021
"1654",1654,1670,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,21066209.31,"total cell volume","abundance","biom","SS",NA,3459399.66,NA,1997285.325,3,250,NA,36.76470588,NA,10223871.553,"total cell volume",2,NA,2326351.233,NA,1343119.51,3,0.8,2947825.984,-2.942463447,1.388174261
"1655",1655,1671,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",17,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,53745077.21,"total cell volume","abundance","biom","SS",NA,7697904.202,NA,4444387.063,3,250,NA,36.76470588,NA,25909649.5284,"total cell volume",2,NA,6189561.887,NA,3573545.222,3,0.8,6984568.901,-3.188219984,1.513728889
"1656",1656,1672,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",19,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,98345067.61,"total cell volume","abundance","biom","SS",NA,NA,NA,NA,3,250,NA,36.76470588,NA,47106075.4198,"total cell volume",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1657",1657,1673,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,677.1584442,"total cell volume","abundance","biom","SS",NA,53744622.52,NA,31029472.28,3,250,NA,36.76470588,NA,628.1696,"total cell volume",2,NA,25908978.22,NA,14958555.55,3,0.8,42188621.7,-9.28949e-07,0.666666667
"1658",1658,1674,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,4393.348322,"total cell volume","abundance","biom","SS",NA,98342307.84,NA,56777957.91,3,250,NA,36.76470588,NA,3532.4573,"total cell volume",2,NA,47104854.92,NA,27196000.67,3,0.8,77104075.34,-8.93225e-06,0.666666667
"1659",1659,1675,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,13676.61936,"total cell volume","abundance","biom","SS",NA,2291.941771,NA,1323.253199,3,250,NA,36.76470588,NA,12478.2547,"total cell volume",2,NA,1590.81273,NA,918.4561578,3,0.8,1972.774978,-0.485961012,0.686346509
"1660",1660,1676,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,82742.96061,"total cell volume","abundance","biom","SS",NA,54982.23946,NA,31744.01075,3,250,NA,36.76470588,NA,61441.4616,"total cell volume",2,NA,8945.797387,NA,5164.858529,3,0.8,39389.55412,-0.432632447,0.682264236
"1661",1661,1677,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,410253.7182,"total cell volume","abundance","biom","SS",NA,148168.1757,NA,85544.93614,3,250,NA,36.76470588,NA,231944.7866,"total cell volume",2,NA,23637.13518,NA,13646.90636,3,0.8,106095.5288,-1.344516088,0.817310292
"1662",1662,1678,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,2481402.338,"total cell volume","abundance","biom","SS",NA,388823.969,NA,224487.6232,3,250,NA,36.76470588,NA,766682.2075,"total cell volume",2,NA,84259.2049,NA,48647.07463,3,0.8,281321.6064,-4.87618467,2.648098078
"1663",1663,1679,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,11509722.9,"total cell volume","abundance","biom","SS",NA,4131449.11,NA,2385293.256,3,250,NA,36.76470588,NA,2076384.0891,"total cell volume",2,NA,249661.6779,NA,144142.2369,3,0.8,2926704.862,-2.578555544,1.220745725
"1664",1664,1680,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,27477107.34,"total cell volume","abundance","biom","SS",NA,1023150.451,NA,590716.1884,3,250,NA,36.76470588,NA,8376776.4007,"total cell volume",2,NA,233317.7925,NA,134706.0903,3,0.8,742049.2026,-20.59198325,36.00248119
"1665",1665,1681,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 1",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",17,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","19",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,5273786.696,"total cell volume","abundance","biom","SS",NA,195617.3256,NA,112939.7156,3,250,NA,36.76470588,NA,52041062.3876,"total cell volume",2,NA,2847498.543,NA,1644004.05,3,0.8,2018231.167,18.53792626,29.30455917
"1666",1666,1682,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 2",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,0.278571429,"growth rate","biom","biom","dSS",NA,0.082142857,NA,0.047425201,3,250,NA,36.76470588,NA,0.1679,"growth rate",2,NA,0.053571429,NA,0.030929479,3,0.8,0.069344599,-1.277264983,0.802617153
"1667",1667,1683,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 2",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,0.378571429,"growth rate","biom","biom","dSS",NA,0.042857143,NA,0.024743583,3,250,NA,36.76470588,NA,0.2393,"growth rate",2,NA,0.021428571,NA,0.012371791,3,0.8,0.033881546,-3.288768767,1.568
"1668",1668,1684,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 2",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,0.35,"growth rate","biom","biom","dSS",NA,0.05,NA,0.028867513,3,250,NA,36.76470588,NA,0.3393,"growth rate",2,NA,0.010714286,NA,0.006185896,3,0.8,0.036157958,-0.237055103,0.671349593
"1669",1669,1685,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 2",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,0.478571429,"growth rate","biom","biom","dSS",NA,0.028571429,NA,0.016495722,3,250,NA,36.76470588,NA,0.4179,"growth rate",2,NA,0.025,NA,0.014433757,3,0.8,0.026845172,-1.809317086,0.939469027
"1670",1670,1686,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 2",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,0.510714286,"growth rate","biom","biom","dSS",NA,0.028571429,NA,0.016495722,3,250,NA,36.76470588,NA,0.4214,"growth rate",2,NA,0.017857143,NA,0.010309826,3,0.8,0.0238244,-2.998126756,1.415730337
"1671",1671,1687,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 2",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Ni_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,0.435714286,"growth rate","biom","biom","dSS",NA,0.010714286,NA,0.006185896,3,250,NA,36.76470588,NA,0.3857,"growth rate",2,NA,0.042857143,NA,0.024743583,3,0.8,0.031237242,-1.280522769,0.803311547
"1672",1672,1688,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,16.06506004,"cell density","abundance","biom","SS",NA,2.035022807,NA,1.174920965,3,250,NA,36.76470588,NA,13.4497,"cell density",2,NA,5.483652829,NA,3.165988437,3,0.8,4.135925904,-0.50587977,0.687992862
"1673",1673,1689,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",2,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,41.4616956,"cell density","abundance","biom","SS",NA,11.90960325,NA,6.876012642,3,250,NA,36.76470588,NA,40.1754,"cell density",NA,NA,0,NA,0,3,0.8,8.421361219,-0.122191964,0.667910906
"1674",1674,1690,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",4,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,150.1310729,"cell density","abundance","biom","SS",NA,83.52260998,NA,48.22180136,3,250,NA,36.76470588,NA,137.5986,"cell density",2,NA,39.85254771,NA,23.00887915,3,0.8,65.43795511,-0.153214099,0.66862288
"1675",1675,1691,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,258.086154,"cell density","abundance","biom","SS",NA,0,NA,0,3,250,NA,36.76470588,NA,237.8141,"cell density",2,NA,120.6580578,NA,69.66196213,3,0.8,85.31813085,-0.19008425,0.669677669
"1676",1676,1692,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,873.3261624,"cell density","abundance","biom","SS",NA,110.6275765,NA,63.87086107,3,250,NA,36.76470588,NA,578.5971,"cell density",2,NA,421.4029199,NA,243.2970893,3,0.8,308.0737587,-0.765346802,0.715479644
"1677",1677,1693,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,2955.209235,"cell density","abundance","biom","SS",NA,0,NA,0,3,250,NA,36.76470588,NA,1728.3184,"cell density",2,NA,1696.62549,NA,979.5471831,3,0.8,1199.695389,-0.818134877,0.72244539
"1678",1678,1694,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,10700.68956,"cell density","abundance","biom","SS",NA,0,NA,0,3,250,NA,36.76470588,NA,4502.6205,"cell density",2,NA,7227.620364,NA,4172.868563,3,0.8,5110.699371,-0.970210703,0.745109067
"1679",1679,1695,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,33838.55153,"cell density","abundance","biom","SS",NA,4908.19967,NA,2833.750401,3,250,NA,36.76470588,NA,11730.2409,"cell density",2,NA,23308.98118,NA,13457.44656,3,0.8,16843.3819,-1.05006516,0.75855307
"1680",1680,1696,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,87332.61624,"cell density","abundance","biom","SS",NA,0,NA,0,3,250,NA,36.76470588,NA,26652.7837,"cell density",2,NA,64631.50583,NA,37315.01729,3,0.8,45701.37605,-1.062197033,0.760688545
"1681",1681,1697,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",18,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,114504.757,"cell density","abundance","biom","SS",NA,60142.92079,NA,34723.53151,3,250,NA,36.76470588,NA,79614.12,"cell density",2,NA,57984.43128,NA,33477.32701,3,0.8,59073.5355,-0.47250447,0.685271706
"1682",1682,1698,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",21,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,76269.85859,"cell density","abundance","biom","SS",NA,25467.67812,NA,14703.77082,3,250,NA,36.76470588,NA,147338.6993,"cell density",2,NA,9740.148055,NA,5623.477102,3,0.8,19280.47086,2.948842537,1.391306025
"1683",1683,1699,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,17.19072202,"cell density","abundance","biom","SS",NA,1.204535939,NA,0.695439149,3,250,NA,36.76470588,NA,14.4018,"cell density",2,NA,3.279960883,NA,1.893686299,3,0.8,2.47073372,-0.903036363,0.734622889
"1684",1684,1700,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",2,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,44.36687331,"cell density","abundance","biom","SS",NA,10.52832178,NA,6.078529414,3,250,NA,36.76470588,NA,43.0193,"cell density",2,NA,10.29642528,NA,5.944643905,3,0.8,10.41301909,-0.103529678,0.667559866
"1685",1685,1701,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",4,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,160.6506004,"cell density","abundance","biom","SS",NA,79.03659245,NA,45.63179793,3,250,NA,36.76470588,NA,147.3387,"cell density",2,NA,82.49299853,NA,47.62735491,3,0.8,80.7832834,-0.131828274,0.668114891
"1686",1686,1702,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,295.5209235,"cell density","abundance","biom","SS",NA,84.88646929,NA,49.0092259,3,250,NA,36.76470588,NA,254.6482,"cell density",2,NA,107.3094909,NA,61.95516347,3,0.8,96.7497791,-0.337966525,0.676185114
"1687",1687,1703,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,1070.068956,"cell density","abundance","biom","SS",NA,626.4002226,NA,361.6523371,3,250,NA,36.76470588,NA,663.4103,"cell density",2,NA,425.5961386,NA,245.7180452,3,0.8,535.4947769,-0.607525933,0.69742398
"1688",1688,1704,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,3620.95835,"cell density","abundance","biom","SS",NA,2686.439136,NA,1551.016358,3,250,NA,36.76470588,NA,1981.6626,"cell density",2,NA,1623.190384,NA,937.149405,3,0.8,2219.425855,-0.590890042,0.695762587
"1689",1689,1705,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,13111.33937,"cell density","abundance","biom","SS",NA,11004.99483,NA,6353.736728,3,250,NA,36.76470588,NA,5162.6334,"cell density",2,NA,4622.285754,NA,2668.677924,3,0.8,8440.243977,-0.753410066,0.713968894
"1690",1690,1706,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,38746.7512,"cell density","abundance","biom","SS",NA,35584.47354,NA,20544.70538,3,250,NA,36.76470588,NA,14401.769,"cell density",2,NA,13691.39815,NA,7904.732409,3,0.8,26960.24055,-0.722396586,0.710154736
"1691",1691,1707,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,107006.8956,"cell density","abundance","biom","SS",NA,99379.90971,NA,57377.01762,3,250,NA,36.76470588,NA,32722.8774,"cell density",2,NA,31722.87739,NA,18315.2118,3,0.8,73765.53194,-0.805623074,0.720752378
"1692",1692,1708,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",18,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,131113.3937,"cell density","abundance","biom","SS",NA,116100.2865,NA,67030.53166,3,250,NA,36.76470588,NA,104665.1211,"cell density",2,NA,103437.374,NA,59719.59572,3,0.8,109951.2775,-0.19243631,0.669752644
"1693",1693,1709,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",21,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,87332.61624,"cell density","abundance","biom","SS",NA,45870.92064,NA,26483.58838,3,250,NA,36.76470588,NA,157768.3204,"cell density",2,NA,156311.6331,NA,90246.56343,3,0.8,115189.9909,0.489179337,0.686608035
"1694",1694,1710,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,17.19072202,"cell density","abundance","biom","SS",NA,6.927924978,NA,3.999839351,3,250,NA,36.76470588,NA,17.6817,"cell density",2,NA,5.563649205,NA,3.212174366,3,0.8,6.282926746,0.062519639,0.666992392
"1695",1695,1711,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",2,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,25.8086154,"cell density","abundance","biom","SS",NA,21.66699839,NA,12.50944735,3,250,NA,36.76470588,NA,35.0392,"cell density",2,NA,2.480311075,NA,1.432008267,3,0.8,15.4209397,0.478860917,0.685775648
"1696",1696,1712,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",4,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,71.27564834,"cell density","abundance","biom","SS",NA,22.17627311,NA,12.80347725,3,250,NA,36.76470588,NA,85.2497,"cell density",2,NA,5.635621224,NA,3.253727431,3,0.8,16.17942081,0.690956396,0.706451728
"1697",1697,1713,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,338.3855153,"cell density","abundance","biom","SS",NA,80.2993613,NA,46.36085786,3,250,NA,36.76470588,NA,312.6436,"cell density",2,NA,131.7489144,NA,76.06527122,3,0.8,109.1003297,-0.188757945,0.669635797
"1698",1698,1714,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,1070.068956,"cell density","abundance","biom","SS",NA,526.4505937,NA,303.946392,3,250,NA,36.76470588,NA,872.1558,"cell density",2,NA,599.4818756,NA,346.1110222,3,0.8,564.1492474,-0.280653653,0.673230539
"1699",1699,1715,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,3874.67512,"cell density","abundance","biom","SS",NA,2729.627551,NA,1575.951201,3,250,NA,36.76470588,NA,2789.6168,"cell density",2,NA,2378.598314,NA,1373.284377,3,0.8,2560.136374,-0.339062653,0.676246957
"1700",1700,1716,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,15013.10729,"cell density","abundance","biom","SS",NA,12601.24259,NA,7275.330801,3,250,NA,36.76470588,NA,9554.2812,"cell density",2,NA,8934.727152,NA,5158.467126,3,0.8,10922.9269,-0.399806838,0.679987126
"1701",1701,1717,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,54361.8362,"cell density","abundance","biom","SS",NA,50487.16108,NA,29148.77604,3,250,NA,36.76470588,NA,30559.6598,"cell density",2,NA,29745.15977,NA,17173.376,3,0.8,41435.0574,-0.459556287,0.684265998
"1702",1702,1718,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,1e+05,"cell density","abundance","biom","SS",NA,90654.80785,NA,52339.57772,3,250,NA,36.76470588,NA,79614.12,"cell density",2,NA,78467.53582,NA,45303.25293,3,0.8,84780.44693,-0.192363978,0.669750325
"1703",1703,1719,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",18,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,66608.46291,"cell density","abundance","biom","SS",NA,46924.26844,NA,27091.73902,3,250,NA,36.76470588,NA,120007.3707,"cell density",2,NA,118599.6554,NA,68473.54295,3,0.8,90188.04029,0.473667308,0.685363393
"1704",1704,1720,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",21,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,58170.91329,"cell density","abundance","biom","SS",NA,7368.732825,NA,4254.33988,3,250,NA,36.76470588,NA,120007.3707,"cell density",2,NA,118279.0523,NA,68288.44268,3,0.8,83798.0681,0.590337785,0.695708225
"1705",1705,1721,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,16.06506004,"cell density","abundance","biom","SS",NA,3.812261465,NA,2.201010183,3,250,NA,36.76470588,NA,12.5606,"cell density",2,NA,0,NA,0,3,0.8,2.695675934,-1.040028294,0.756804904
"1706",1706,1722,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",2,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,27.61699813,"cell density","abundance","biom","SS",NA,0,NA,0,3,250,NA,36.76470588,NA,28.5394,"cell density",2,NA,2.020213373,NA,1.166370735,3,0.8,1.428506575,0.516594484,0.688905822
"1707",1707,1723,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",4,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,131.1133937,"cell density","abundance","biom","SS",NA,37.66147229,NA,21.74386116,3,250,NA,36.76470588,NA,128.5023,"cell density",2,NA,16.42827695,NA,9.484870118,3,0.8,29.05404256,-0.07189627,0.667097423
"1708",1708,1724,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,225.3933905,"cell density","abundance","biom","SS",NA,162.0741216,NA,93.57353773,3,250,NA,36.76470588,NA,291.9756,"cell density",2,NA,66.49658733,NA,38.3918226,3,0.8,123.8745676,0.429997498,0.682074821
"1709",1709,1725,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,1225.279857,"cell density","abundance","biom","SS",NA,1186.584842,NA,685.0750779,3,250,NA,36.76470588,NA,1507.3629,"cell density",2,NA,614.5750176,NA,354.8250518,3,0.8,944.9037092,0.238824794,0.671419774
"1710",1710,1726,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,7626.985859,"cell density","abundance","biom","SS",NA,4625.812715,NA,2670.714216,3,250,NA,36.76470588,NA,7267.5184,"cell density",2,NA,4462.72251,NA,2576.554043,3,0.8,4544.999201,-0.063272615,0.667000285
"1711",1711,1727,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,44366.87331,"cell density","abundance","biom","SS",NA,5620.122105,NA,3244.77901,3,250,NA,36.76470588,NA,37519.5331,"cell density",2,NA,8544.96422,NA,4933.437393,3,0.8,7231.94946,-0.757454427,0.714478101
"1712",1712,1728,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,140300.3723,"cell density","abundance","biom","SS",NA,73691.90941,NA,42546.04373,3,250,NA,36.76470588,NA,120007.3707,"cell density",2,NA,28723.08124,NA,16583.27868,3,0.8,55926.34848,-0.290281803,0.673688627
"1713",1713,1729,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,150131.0729,"cell density","abundance","biom","SS",NA,113921.4894,NA,65772.60257,3,250,NA,36.76470588,NA,147338.6993,"cell density",2,NA,56054.40983,NA,32363.02861,3,0.8,89778.06695,-0.024882457,0.666718261
"1714",1714,1730,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",18,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,87332.61624,"cell density","abundance","biom","SS",NA,57780.52389,NA,33359.60102,3,250,NA,36.76470588,NA,104665.1211,"cell density",2,NA,35229.20679,NA,20339.59202,3,0.8,47852.30377,0.289766694,0.673663728
"1715",1715,1731,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",21,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,71275.64834,"cell density","abundance","biom","SS",NA,45467.03294,NA,26250.40371,3,250,NA,36.76470588,NA,69435.9143,"cell density",2,NA,16619.09093,NA,9595.036624,3,0.8,34230.43432,-0.042996452,0.666820725
"1716",1716,1732,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,18.39525796,"cell density","abundance","biom","SS",NA,3.382150669,NA,1.952685599,3,250,NA,36.76470588,NA,15.4212,"cell density",2,NA,1.091617549,NA,0.630245686,3,0.8,2.513023281,-0.946759285,0.741362762
"1717",1717,1733,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",2,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,33.83855153,"cell density","abundance","biom","SS",NA,16.96362893,NA,9.793955729,3,250,NA,36.76470588,NA,32.7229,"cell density",2,NA,16.60237395,NA,9.585385068,3,0.8,16.78397341,-0.05317807,0.666902326
"1718",1718,1734,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",4,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,150.1310729,"cell density","abundance","biom","SS",NA,27.60308715,NA,15.9366498,3,250,NA,36.76470588,NA,147.3387,"cell density",2,NA,27.3313286,NA,15.77974992,3,0.8,27.46754397,-0.081328671,0.667217863
"1719",1719,1735,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,258.086154,"cell density","abundance","biom","SS",NA,104.009681,NA,60.05001732,3,250,NA,36.76470588,NA,334.7746,"cell density",2,NA,62.1006845,NA,35.85384691,3,0.8,85.65777477,0.71623086,0.709415554
"1720",1720,1736,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,1403.003723,"cell density","abundance","biom","SS",NA,332.9347675,NA,192.2199776,3,250,NA,36.76470588,NA,1614.0642,"cell density",2,NA,950.6539007,NA,548.8602855,3,0.8,712.2458839,0.237064681,0.671349972
"1721",1721,1737,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,8733.261624,"cell density","abundance","biom","SS",NA,5570.983964,NA,3216.409091,3,250,NA,36.76470588,NA,7781.9621,"cell density",2,NA,6467.306803,NA,3733.901324,3,0.8,6035.806475,-0.126087484,0.667991504
"1722",1722,1738,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,50802.18047,"cell density","abundance","biom","SS",NA,40802.18047,NA,23557.14988,3,250,NA,36.76470588,NA,40175.4173,"cell density",2,NA,37188.33265,NA,21470.69387,3,0.8,39037.09784,-0.21777773,0.670618928
"1723",1723,1739,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,150131.0729,"cell density","abundance","biom","SS",NA,126012.4259,NA,72753.30801,3,250,NA,36.76470588,NA,137598.5513,"cell density",2,NA,131679.1575,NA,76024.99706,3,0.8,128876.9413,-0.077795277,0.667171009
"1724",1724,1740,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,171907.2202,"cell density","abundance","biom","SS",NA,130445.5246,NA,75312.75874,3,250,NA,36.76470588,NA,157768.3204,"cell density",2,NA,148845.6459,NA,85936.07372,3,0.8,139948.314,-0.080823552,0.667211037
"1725",1725,1741,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",18,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,1e+05,"cell density","abundance","biom","SS",NA,18385.99207,NA,10615.15747,3,250,NA,36.76470588,NA,120007.3707,"cell density",2,NA,99733.77916,NA,57581.32424,3,0.8,71710.77816,0.22320071,0.670818213
"1726",1726,1742,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",21,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,71275.64834,"cell density","abundance","biom","SS",NA,0,NA,0,3,250,NA,36.76470588,NA,79614.12,"cell density",2,NA,51074.67359,NA,29487.97654,3,0.8,36115.24804,0.184708058,0.669509756
"1727",1727,1743,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",0,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,15.01310729,"cell density","abundance","biom","SS",NA,4.671087184,NA,2.696853443,3,250,NA,36.76470588,NA,14.4018,"cell density",2,NA,5.871822544,NA,3.390098326,3,0.8,5.305532748,-0.092181244,0.667374782
"1728",1728,1744,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",2,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,38.7467512,"cell density","abundance","biom","SS",NA,19.42416209,NA,11.21454521,3,250,NA,36.76470588,NA,40.1754,"cell density",2,NA,16.38013499,NA,9.457075346,3,0.8,17.96673169,0.063613843,0.667003893
"1729",1729,1745,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",4,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,122.5279857,"cell density","abundance","biom","SS",NA,27.60308715,NA,15.9366498,3,250,NA,36.76470588,NA,137.5986,"cell density",2,NA,9.096254193,NA,5.251724807,3,0.8,20.55081824,0.586665325,0.695348017
"1730",1730,1746,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",5,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,508.0218047,"cell density","abundance","biom","SS",NA,93.40484871,NA,53.92731455,3,250,NA,36.76470588,NA,504.6268,"cell density",2,NA,191.9832104,NA,110.8415582,3,0.8,150.966915,-0.017990811,0.666693639
"1731",1731,1747,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",7,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,2761.699813,"cell density","abundance","biom","SS",NA,1450.565876,NA,837.484599,3,250,NA,36.76470588,NA,2432.9804,"cell density",2,NA,1672.324729,NA,965.5171325,3,0.8,1565.377169,-0.167994985,0.669018526
"1732",1732,1748,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",9,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,15013.10729,"cell density","abundance","biom","SS",NA,11392.14894,NA,6577.260257,3,250,NA,36.76470588,NA,13449.7085,"cell density",2,NA,11942.34558,NA,6894.916438,3,0.8,11670.49004,-0.107169368,0.667623773
"1733",1733,1749,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",11,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,47475.61379,"cell density","abundance","biom","SS",NA,36774.92423,NA,21232.0124,3,250,NA,36.76470588,NA,49325.2513,"cell density",2,NA,45900.30742,NA,26500.55484,3,0.8,41588.65995,0.035579652,0.666772159
"1734",1734,1750,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",13,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,71275.64834,"cell density","abundance","biom","SS",NA,43658.65021,NA,25206.33345,3,250,NA,36.76470588,NA,104665.1211,"cell density",2,NA,97878.03796,NA,56509.91156,3,0.8,75783.20412,0.352473592,0.677019803
"1735",1735,1751,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",15,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,47475.61379,"cell density","abundance","biom","SS",NA,14771.27465,NA,8528.199395,3,250,NA,36.76470588,NA,104665.1211,"cell density",2,NA,94434.52378,NA,54521.79773,3,0.8,67587.23932,0.676926685,0.704852478
"1736",1736,1752,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",18,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,36209.5835,"cell density","abundance","biom","SS",NA,63790.4165,NA,36829.41414,3,250,NA,36.76470588,NA,79614.12,"cell density",2,NA,54723.27708,NA,31594.49875,3,0.8,59430.01889,0.584277606,0.695115027
"1737",1737,1753,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 4",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",21,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","21",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,31622.7766,"cell density","abundance","biom","SS",NA,49991.23133,NA,28862.45087,3,250,NA,36.76470588,NA,60558.9334,"cell density",2,NA,25519.71138,NA,14733.81224,3,0.8,39688.65631,0.583263018,0.695016312
"1738",1738,1754,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 5",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,0.249122807,"growth rate","biom","biom","dSS",NA,0.014035088,NA,0.008103162,3,250,NA,36.76470588,NA,0.1298,"growth rate",2,NA,0.010526316,NA,0.006077371,3,0.8,0.012405382,-7.693321779,5.598933333
"1739",1739,1755,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 5",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,0.442105263,"growth rate","biom","biom","dSS",NA,0.010526316,NA,0.006077371,3,250,NA,36.76470588,NA,0.3825,"growth rate",2,NA,0.010526316,NA,0.006077371,3,0.8,0.010526316,-4.533333333,2.379259259
"1740",1740,1756,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 5",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.01,NA,NA,NA,1,680,NA,100,NA,0.50877193,"growth rate","biom","biom","dSS",NA,0.014035088,NA,0.008103162,3,250,NA,36.76470588,NA,0.3298,"growth rate",2,NA,0.021052632,NA,0.012154743,3,0.8,0.017891297,-8.001538314,6.002051282
"1741",1741,1757,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"red",NA,"Fig. 5",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,0.329824561,"growth rate","biom","biom","dSS",NA,0.014035088,NA,0.008103162,3,250,NA,36.76470588,NA,0.2386,"growth rate",2,NA,0.014035088,NA,0.008103162,3,0.8,0.014035088,-5.2,2.92
"1742",1742,1758,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"blue",NA,"Fig. 5",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,0.49122807,"growth rate","biom","biom","dSS",NA,0.010526316,NA,0.006077371,3,250,NA,36.76470588,NA,0.4632,"growth rate",2,NA,0.010526316,NA,0.006077371,3,0.8,0.010526316,-2.133333333,1.045925926
"1743",1743,1759,"935","Rodriguez, IB; Ho, TY",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","PLOS ONE",1,"white",NA,"Fig. 5",NA,NA,"Lab","culture",21.4166667,-158,"North Pacific Ocean","Trichodesmium erythraeum","phytoplankton",3,"microcosm","culture flask",1,NA,"No","Fe_lightcolor","light reduced","12",NA,NA,26,NA,NA,NA,NA,0.1,NA,NA,NA,1,680,NA,100,NA,0.529824561,"growth rate","biom","biom","dSS",NA,0.014035088,NA,0.008103162,3,250,NA,36.76470588,NA,0.4105,"growth rate",2,NA,0.014035088,NA,0.008103162,3,0.8,0.014035088,-6.8,4.52
"1744",1744,1760,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,20,NA,76.41,NA,NA,NA,1,200,NA,100,NA,1.805343511,"growth rate","biom","biom","dSS",NA,0.160305344,NA,0.071690729,5,50,NA,25,NA,1.1527,"growth rate",2,NA,0.229007634,NA,0.102415327,5,0.903225806,0.197664235,-2.982380569,0.844729693
"1745",1745,1761,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,25,NA,80.95,NA,NA,NA,1,200,NA,100,NA,1.370229008,"growth rate","biom","biom","dSS",NA,0.057251908,NA,0.025603832,5,50,NA,25,NA,1.0496,"growth rate",2,NA,0.114503817,NA,0.051207664,5,0.903225806,0.090523215,-3.199000885,0.911680333
"1746",1746,1762,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,30,NA,84.88,NA,NA,NA,1,200,NA,100,NA,1.324427481,"growth rate","biom","biom","dSS",NA,0.103053435,NA,0.046086897,5,50,NA,25,NA,0.9237,"growth rate",2,NA,0.125954198,NA,0.05632843,5,0.903225806,0.115074912,-3.14560144,0.894740421
"1747",1747,1763,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,35,NA,89.1,NA,NA,NA,1,200,NA,100,NA,0.877862595,"growth rate","biom","biom","dSS",NA,0.217557252,NA,0.097294561,5,50,NA,25,NA,0.374,"growth rate",2,NA,0.251908397,NA,0.11265686,5,0.903225806,0.23536036,-1.933462073,0.586913779
"1748",1748,1764,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,40,NA,87.8,NA,NA,NA,1,200,NA,100,NA,0.832061069,"growth rate","biom","biom","dSS",NA,0.183206107,NA,0.081932262,5,50,NA,25,NA,0.5229,"growth rate",2,NA,0.309160305,NA,0.138260692,5,0.903225806,0.254110775,-1.098896991,0.46037873
"1749",1749,1765,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,20,NA,76.41,NA,NA,NA,1,200,NA,100,NA,1.805343511,"growth rate","biom","biom","dSS",NA,0.160305344,NA,0.071690729,5,100,NA,50,NA,1.4389,"growth rate",2,NA,0.263358779,NA,0.117777626,5,0.903225806,0.218008772,-1.518071792,0.515227098
"1750",1750,1766,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,25,NA,80.95,NA,NA,NA,1,200,NA,100,NA,1.370229008,"growth rate","biom","biom","dSS",NA,0.057251908,NA,0.025603832,5,100,NA,50,NA,1.1756,"growth rate",2,NA,0.114503817,NA,0.051207664,5,0.903225806,0.090523215,-1.942250537,0.588616857
"1751",1751,1767,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,30,NA,84.88,NA,NA,NA,1,200,NA,100,NA,1.324427481,"growth rate","biom","biom","dSS",NA,0.103053435,NA,0.046086897,5,100,NA,50,NA,1.187,"growth rate",2,NA,0.080152672,NA,0.035845365,5,0.903225806,0.092315928,-1.344376478,0.490367406
"1752",1752,1768,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,35,NA,89.1,NA,NA,NA,1,200,NA,100,NA,0.877862595,"growth rate","biom","biom","dSS",NA,0.217557252,NA,0.097294561,5,100,NA,50,NA,0.9237,"growth rate",2,NA,0.183206107,NA,0.081932262,5,0.903225806,0.201116428,0.205697373,0.40211557
"1753",1753,1769,"936","Pliego-Cortes, H; Caamal-Fuentes, E; Montero-Munoz, J; Freile-Pelegrin, Y; Robledo, D",2017,"Interactive effects of spectral quality and trace metal availability on the growth of Trichodesmium and Symbiodinium","JOURNAL OF APPLIED PHYCOLOGY",1,NA,NA,"Fig. 1",NA,NA,"Lab","coastal",21.341111,-89.306944,"Cinvestav Coastal Marine Station","Rhodymenia pseudopalmata","seaweed",42,"microcosm","culture flask",0.5,NA,"No","sal","reduced light","12",NA,NA,25,8.2,NA,40,NA,87.8,NA,NA,NA,1,200,NA,100,NA,0.832061069,"growth rate","biom","biom","dSS",NA,0.183206107,NA,0.081932262,5,100,NA,50,NA,0.9351,"growth rate",2,NA,0.160305344,NA,0.071690729,5,0.903225806,0.172136981,0.540735182,0.414619727
"1754",1754,1770,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.061904762,"chl a (pg cell)","cellular content","phys","Q",NA,0.011904762,NA,0.006873217,3,20,NA,10,NA,0.1429,"chl a (pg cell)",1,NA,0.001190476,NA,0.000687322,3,0.8,0.008459923,7.655141287,5.55009901
"1755",1755,1771,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.64,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.020238095,"chl a (pg cell)","cellular content","phys","Q",NA,0.005952381,NA,0.003436609,3,20,NA,10,NA,0.2607,"chl a (pg cell)",1,NA,0.039285714,NA,0.022681618,3,0.8,0.028096247,6.847211753,4.5736924
"1756",1756,1772,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.91,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.05952381,"chl a (pg cell)","cellular content","phys","Q",NA,0.014285714,NA,0.008247861,3,20,NA,10,NA,0.2405,"chl a (pg cell)",1,NA,0.027380952,NA,0.0158084,3,0.8,0.021838019,6.628893484,4.328519069
"1757",1757,1773,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.061904762,"chl a (pg cell)","cellular content","phys","Q",NA,0.011904762,NA,0.006873217,3,50,NA,25,NA,0.1036,"chl a (pg cell)",1,NA,0.010714286,NA,0.006185896,3,0.8,0.011325177,2.943294655,1.388581952
"1758",1758,1774,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,9.46,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.020238095,"chl a (pg cell)","cellular content","phys","Q",NA,0.005952381,NA,0.003436609,3,50,NA,25,NA,0.1202,"chl a (pg cell)",1,NA,0.004761905,NA,0.002749287,3,0.8,0.00539011,14.8419971,19.02373984
"1759",1759,1775,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,9.27,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.05952381,"chl a (pg cell)","cellular content","phys","Q",NA,0.014285714,NA,0.008247861,3,50,NA,25,NA,0.0869,"chl a (pg cell)",1,NA,0.001190476,NA,0.000687322,3,0.8,0.01013654,2.160970408,1.055816092
"1760",1760,1776,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.48,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.061904762,"chl a (pg cell)","cellular content","phys","Q",NA,0.011904762,NA,0.006873217,3,100,NA,50,NA,0.0429,"chl a (pg cell)",1,NA,0.002380952,NA,0.001374643,3,0.8,0.008584646,-1.775040628,0.929230769
"1761",1761,1777,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,9.79,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.020238095,"chl a (pg cell)","cellular content","phys","Q",NA,0.005952381,NA,0.003436609,3,100,NA,50,NA,0.0298,"chl a (pg cell)",1,NA,0.005952381,NA,0.003436609,3,0.8,0.005952381,1.28,0.8032
"1762",1762,1778,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 4",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,9.72,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.05952381,"chl a (pg cell)","cellular content","phys","Q",NA,0.014285714,NA,0.008247861,3,100,NA,50,NA,0.0655,"chl a (pg cell)",1,NA,0.003571429,NA,0.002061965,3,0.8,0.010412414,0.45732956,0.684095861
"1763",1763,1779,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",16,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.937241379,"growth rate","biom","biom","dSS",NA,0.049655172,NA,0.028668427,3,20,NA,10,NA,0.5214,"growth rate",2,NA,0.043448276,NA,0.025084874,3,0.8,0.046655058,-7.130837928,4.904070796
"1764",1764,1780,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",16,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.937241379,"growth rate","biom","biom","dSS",NA,0.049655172,NA,0.028668427,3,50,NA,25,NA,0.6455,"growth rate",2,NA,0.01862069,NA,0.01075066,3,0.8,0.037499108,-6.223596282,3.894429224
"1765",1765,1781,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",16,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.48,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.937241379,"growth rate","biom","biom","dSS",NA,0.049655172,NA,0.028668427,3,100,NA,50,NA,0.9186,"growth rate",2,NA,0.031034483,NA,0.017917767,3,0.8,0.041405164,-0.359775211,0.677453184
"1766",1766,1782,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"based on abundance",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",16,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.986896552,"growth rate","biom","biom","dSS",NA,0.093103448,NA,0.053753301,3,20,NA,10,NA,0.4903,"growth rate",2,NA,0.043448276,NA,0.025084874,3,0.8,0.072649862,-5.467889009,3.158150852
"1767",1767,1783,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"based on abundance",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",16,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.986896552,"growth rate","biom","biom","dSS",NA,0.093103448,NA,0.053753301,3,50,NA,25,NA,0.7883,"growth rate",2,NA,0.055862069,NA,0.032251981,3,0.8,0.07677507,-2.069637334,1.023616558
"1768",1768,1784,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"based on abundance",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",16,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.48,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.986896552,"growth rate","biom","biom","dSS",NA,0.093103448,NA,0.053753301,3,100,NA,50,NA,1.0179,"growth rate",2,NA,0.043448276,NA,0.025084874,3,0.8,0.072649862,0.341743063,0.676399027
"1769",1769,1785,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",1,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,413691.0606,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,20,NA,10,NA,444555.6522,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1770",1770,1786,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",2,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,NA,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,20,NA,10,NA,541228.5302,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1771",1771,1787,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",3,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1070958.71,"cell density","abundance","abundance","SS",NA,100792.005,NA,58192.29122,3,20,NA,10,NA,658923.85,"cell density",2,NA,49160.8775,NA,28383.04586,3,0.8,79296.34339,-4.15691158,2.10665949
"1772",1772,1788,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1589149.563,"cell density","abundance","abundance","SS",NA,245971.723,NA,142011.8405,3,20,NA,10,NA,909865.6568,"cell density",2,NA,85630.9241,NA,49439.03708,3,0.8,184166.6958,-2.950735052,1.392236446
"1773",1773,1789,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",5,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,2674335.622,"cell density","abundance","abundance","SS",NA,414140.999,NA,239104.4173,3,20,NA,10,NA,1211976.8325,"cell density",2,NA,67119.9576,NA,38751.72559,3,0.8,296662.987,-3.943488343,1.962591693
"1774",1774,1790,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",7,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,3081413.635,"cell density","abundance","abundance","SS",NA,213936.26,NA,123516.1573,3,20,NA,10,NA,1930300.8415,"cell density",2,NA,107034.411,NA,61796.346,3,0.8,169152.429,-5.444144317,3.136558945
"1775",1775,1791,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,3819592.619,"cell density","abundance","abundance","SS",NA,1383439.7,NA,798729.2832,3,20,NA,10,NA,2226599.1834,"cell density",2,NA,253774.104,NA,146516.5473,3,0.8,994561.8883,-1.281362943,0.803490916
"1776",1776,1792,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",9,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4174151.252,"cell density","abundance","abundance","SS",NA,298178.799,NA,172153.6099,3,20,NA,10,NA,3074567.9162,"cell density",2,NA,170483.564,NA,98428.73157,3,0.8,242873.6727,-3.621910348,1.759852881
"1777",1777,1793,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",11,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4164877.889,"cell density","abundance","abundance","SS",NA,630411.438,NA,363968.2134,3,20,NA,10,NA,3606635.6628,"cell density",2,NA,269083.254,NA,155355.2891,3,0.8,484677.4075,-0.921424795,0.737418638
"1778",1778,1794,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4221380.945,"cell density","abundance","abundance","SS",NA,359618.085,NA,207625.5982,3,20,NA,10,NA,3999604.4734,"cell density",2,NA,619066.718,NA,357418.3363,3,0.8,506245.3794,-0.350464784,0.67690213
"1779",1779,1795,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",1,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,413691.0606,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,50,NA,25,NA,436630.0648,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1780",1780,1796,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",2,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,NA,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,50,NA,25,NA,636345.7997,"cell density",2,NA,35285.1206,NA,20371.87388,3,0.8,NA,NA,NA
"1781",1781,1797,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",3,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1070958.71,"cell density","abundance","abundance","SS",NA,100792.005,NA,58192.29122,3,50,NA,25,NA,788787.877,"cell density",2,NA,58849.7505,NA,33976.91929,3,0.8,82529.75647,-2.735215467,1.290116971
"1782",1782,1798,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1589149.563,"cell density","abundance","abundance","SS",NA,245971.723,NA,142011.8405,3,50,NA,25,NA,995431.4632,"cell density",2,NA,873000.434,NA,504027.0356,3,0.8,641339.1639,-0.740597965,0.712373779
"1783",1783,1799,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",5,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,2674335.622,"cell density","abundance","abundance","SS",NA,414140.999,NA,239104.4173,3,50,NA,25,NA,1325953.8513,"cell density",2,NA,124790.57,NA,72047.86918,3,0.8,305847.5547,-3.526938175,1.703274407
"1784",1784,1800,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,NA,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,50,NA,25,NA,1766222.6691,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1785",1785,1801,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",7,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,3081413.635,"cell density","abundance","abundance","SS",NA,213936.26,NA,123516.1573,3,50,NA,25,NA,2668394.2737,"cell density",2,NA,1101254.71,NA,635809.7033,3,0.8,793262.4596,-0.416527324,0.681124584
"1786",1786,1802,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,3819592.619,"cell density","abundance","abundance","SS",NA,1383439.7,NA,798729.2832,3,50,NA,25,NA,3023114.1459,"cell density",2,NA,1290862.21,NA,745279.6444,3,0.8,1337951.914,-0.476237428,0.685566841
"1787",1787,1803,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",9,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4174151.252,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,50,NA,25,NA,3244626.9619,"cell density",2,NA,401874.144,NA,232022.1452,3,0.8,NA,NA,NA
"1788",1788,1804,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",11,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4164877.889,"cell density","abundance","abundance","SS",NA,298178.799,NA,172153.6099,3,50,NA,25,NA,4395818.7054,"cell density",2,NA,1564898.99,NA,903494.8531,3,0.8,1126458.931,0.164011886,0.668908325
"1789",1789,1805,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",13,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4081538.182,"cell density","abundance","abundance","SS",NA,630411.438,NA,363968.2134,3,50,NA,25,NA,4974636.6327,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1790",1790,1806,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4221380.945,"cell density","abundance","abundance","SS",NA,359618.085,NA,207625.5982,3,50,NA,25,NA,5238471.0174,"cell density",2,NA,1133123.44,NA,654209.1231,3,0.8,840622.9527,0.967939378,0.74474222
"1791",1791,1807,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",1,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,413691.0606,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,100,NA,50,NA,436658.6276,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1792",1792,1808,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",2,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,NA,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,100,NA,50,NA,NA,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1793",1793,1809,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",3,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1070958.71,"cell density","abundance","abundance","SS",NA,100792.005,NA,58192.29122,3,100,NA,50,NA,1051865.5395,"cell density",2,NA,119885.176,NA,69215.73864,3,0.8,110750.8097,-0.137918057,0.668251783
"1794",1794,1810,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1589149.563,"cell density","abundance","abundance","SS",NA,245971.723,NA,142011.8405,3,100,NA,50,NA,1770271.0725,"cell density",2,NA,166606.956,NA,96190.5709,3,0.8,210071.3763,0.689752266,0.706313182
"1795",1795,1811,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",5,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,2674335.622,"cell density","abundance","abundance","SS",NA,414140.999,NA,239104.4173,3,100,NA,50,NA,2626657.2698,"cell density",2,NA,461617.327,NA,266514.888,3,0.8,438522.1338,-0.08698006,0.667297128
"1796",1796,1812,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,NA,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,100,NA,50,NA,NA,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1797",1797,1813,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",7,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,3081413.635,"cell density","abundance","abundance","SS",NA,213936.26,NA,123516.1573,3,100,NA,50,NA,3371417.2145,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1798",1798,1814,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,3819592.619,"cell density","abundance","abundance","SS",NA,1383439.7,NA,798729.2832,3,100,NA,50,NA,3684373.3846,"cell density",2,NA,275142.098,NA,158853.3643,3,0.8,997398.7612,-0.108457512,0.667646919
"1799",1799,1815,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",9,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4174151.252,"cell density","abundance","abundance","SS",NA,NA,NA,NA,3,100,NA,50,NA,3815097.8549,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1800",1800,1816,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",11,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4164877.889,"cell density","abundance","abundance","SS",NA,298178.799,NA,172153.6099,3,100,NA,50,NA,4639565.0982,"cell density",2,NA,257262.0329,NA,148530.304,3,0.8,278472.9338,1.363686453,0.821636729
"1801",1801,1817,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",13,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4081538.182,"cell density","abundance","abundance","SS",NA,630411.438,NA,363968.2134,3,100,NA,50,NA,4885948.2595,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1802",1802,1818,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"OD",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,4221380.945,"cell density","abundance","abundance","SS",NA,359618.085,NA,207625.5982,3,100,NA,50,NA,5145078.9756,"cell density",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1803",1803,1819,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.13,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.225077913,"Pmax","productivity","phys","dQ",NA,1.174930988,NA,0.678346722,3,20,NA,10,NA,2.3626,"Pmax",1,NA,0.240752007,NA,0.138998236,3,0.8,0.848063781,1.073099744,0.762628588
"1804",1804,1820,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.898100824,"Pmax","productivity","phys","dQ",NA,NA,NA,NA,3,20,NA,10,NA,2.508,"Pmax",1,NA,0.347765397,NA,0.200782446,3,0.8,NA,NA,NA
"1805",1805,1821,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.48,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.715795862,"Pmax","productivity","phys","dQ",NA,0.029300146,NA,0.016916447,3,20,NA,10,NA,1.9286,"Pmax",1,NA,0.296908841,NA,0.171420399,3,0.8,0.210966062,4.598937624,2.429185606
"1806",1806,1822,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.225077913,"Pmax","productivity","phys","dQ",NA,1.174930988,NA,0.678346722,3,50,NA,25,NA,1.8277,"Pmax",1,NA,0.344670673,NA,0.198995706,3,0.8,0.86581196,0.556789108,0.692501176
"1807",1807,1823,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.48,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.898100824,"Pmax","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,25,NA,1.6711,"Pmax",1,NA,0.20570283,NA,0.118762584,3,0.8,NA,NA,NA
"1808",1808,1824,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.715795862,"Pmax","productivity","phys","dQ",NA,0.029300146,NA,0.016916447,3,50,NA,25,NA,1.1002,"Pmax",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1809",1809,1825,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,1.225077913,"Pmax","productivity","phys","dQ",NA,1.174930988,NA,0.678346722,3,100,NA,50,NA,1.7634,"Pmax",1,NA,0.121922046,NA,0.070391726,3,0.8,0.835262776,0.515552425,0.688816192
"1810",1810,1826,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",8,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.43,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.898100824,"Pmax","productivity","phys","dQ",NA,NA,NA,NA,3,100,NA,50,NA,1.2251,"Pmax",1,NA,0.118245535,NA,0.068269092,3,0.8,NA,NA,NA
"1811",1811,1827,"946","Palacios, YM; Vonshak, A; Beardall, J",2018,"Photosynthetic and growth responses of Nannochloropsis oculata (Eustigmatophyceae) during batch cultures in relation to light intensity","PHYCOLOGIA",1,"PS",NA,"Fig. 6",NA,NA,"Lab","culture",NA,NA,NA,"Nannochloropsis oculata","phytoplankton",15,"microcosm","culture flask",2,NA,"No","none","gradient","16",NA,NA,20,8.48,NA,NA,NA,NA,NA,NA,NA,0,200,NA,100,NA,0.715795862,"Pmax","productivity","phys","dQ",NA,0.029300146,NA,0.016916447,3,100,NA,50,NA,0.797,"Pmax",1,NA,0.037174898,NA,0.021462938,3,0.8,0.033469924,1.941198839,0.980687744
"1812",1812,1828,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",0,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.017152066,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0153,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1813",1813,1829,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",0.8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.016179746,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0156,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1814",1814,1830,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.022521219,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0234,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1815",1815,1831,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1.9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.034550419,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.02,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1816",1816,1832,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.045365821,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0243,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1817",1817,1833,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2.8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.084542029,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0248,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1818",1818,1834,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",3.1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.12719963,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0302,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1819",1819,1835,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",3.9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.343041316,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0279,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1820",1820,1836,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",4.1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.50618744,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0307,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1821",1821,1837,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",5,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.746923802,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0396,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1822",1822,1838,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",6.2,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.82322307,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.1047,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1823",1823,1839,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",7,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.82322307,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.2069,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1824",1824,1840,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.664640526,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.3364,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1825",1825,1841,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.568854038,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.58,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1826",1826,1842,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",10,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.385510233,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.603,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1827",1827,1843,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",12,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.11998891,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.7325,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1828",1828,1844,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",14,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.024343604,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.2109,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1829",1829,1845,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",16,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.009569055,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.1027,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1830",1830,1846,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",18,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.00868216,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0767,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1831",1831,1847,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",0,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.017152066,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0178,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1832",1832,1848,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",0.8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.016179746,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0165,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1833",1833,1849,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.022521219,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0268,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1834",1834,1850,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1.9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.034550419,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0274,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1835",1835,1851,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.045365821,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0373,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1836",1836,1852,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2.8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.084542029,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0472,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1837",1837,1853,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",3.1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.12719963,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0683,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1838",1838,1854,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",3.9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.343041316,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0782,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1839",1839,1855,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",4.1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.50618744,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.1027,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1840",1840,1856,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",5,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.746923802,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0932,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1841",1841,1857,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",6.2,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.82322307,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0829,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1842",1842,1858,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",7,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.82322307,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0752,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1843",1843,1859,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.664640526,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0573,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1844",1844,1860,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.568854038,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0352,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1845",1845,1861,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",10,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.385510233,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0258,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1846",1846,1862,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",12,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.11998891,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0182,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1847",1847,1863,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",14,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.024343604,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.015,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1848",1848,1864,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",16,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.009569055,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0119,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1849",1849,1865,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",18,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.00868216,"fluorescence","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0108,"fluorescence",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1850",1850,1866,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",0,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.043496024,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0436,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1851",1851,1867,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.044241982,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0444,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1852",1852,1868,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.045928429,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0455,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1853",1853,1869,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",3,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.048004574,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0458,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1854",1854,1870,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",4,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.055375377,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0472,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1855",1855,1871,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",5,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.064313889,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.047,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1856",1856,1872,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",6,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.069075146,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0475,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1857",1857,1873,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",7,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.071464742,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0495,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1858",1858,1874,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.067910481,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0497,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1859",1859,1875,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.069546586,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0516,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1860",1860,1876,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",10,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.071222109,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0535,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1861",1861,1877,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",12,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.070259786,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0581,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1862",1862,1878,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",14,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.072443569,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0558,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1863",1863,1879,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",16,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.077542514,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0581,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1864",1864,1880,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",18,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,7.2,176,NA,NA,20,3,170,NA,100,NA,0.081323845,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0593,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1865",1865,1881,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",0,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.043496024,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0429,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1866",1866,1882,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",1,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.044241982,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0441,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1867",1867,1883,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",2,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.045928429,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0448,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1868",1868,1884,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LL",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",3,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.048004574,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0462,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1869",1869,1885,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",4,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.055375377,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0469,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1870",1870,1886,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",5,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.064313889,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.048,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1871",1871,1887,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",6,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.069075146,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0487,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1872",1872,1888,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",7,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.071464742,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0487,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1873",1873,1889,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",8,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.067910481,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0485,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1874",1874,1890,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",9,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.069546586,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0492,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1875",1875,1891,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",10,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.071222109,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0493,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1876",1876,1892,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",12,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.070259786,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0493,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1877",1877,1893,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",14,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.072443569,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0497,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1878",1878,1894,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",16,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.077542514,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.0478,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1879",1879,1895,"951","Gross, S; Kourtchenko, O; Rajala, T; Andersson, B; Fernandez, L; Blomberg, A; Godhe, A",2018,"Optimization of a high-throughput phenotyping method for chain-forming phytoplankton species","LIMNOLOGY AND OCEANOGRAPHY-METHODS",1,"LN",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Skeletonema marinoi","phytoplankton",18,"microcosm","culture flask",0.04,NA,"No","nut","reduced light","12",NA,NA,16,NA,NA,26,1.125,27.5,NA,NA,3.13,3,170,NA,100,NA,0.081323845,"OD","biom","biom","SS",NA,NA,NA,NA,2,18,NA,10.58823529,NA,0.049,"OD",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"1880",1880,1896,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",1,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.532960894,"Fv/Fm","productivity","phys","dQ",NA,0.010055866,NA,0.005805757,3,62.25,NA,42.85714286,0.578212291,0.543,"Fv/Fm",1,NA,0.015083799,NA,0.008708635,3,0.8,0.012818764,0.627571632,0.699487179
"1881",1881,1897,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",2,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,8.131914894,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.57150838,"Fv/Fm","productivity","phys","dQ",NA,0.011731844,NA,0.006773383,3,62.25,NA,42.85714286,0.578212291,0.5581,"Fv/Fm",1,NA,0.013407821,NA,0.007741009,3,0.8,0.012597734,-0.851443335,0.727079646
"1882",1882,1898,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",3,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.62849162,"Fv/Fm","productivity","phys","dQ",NA,0.015083799,NA,0.008708635,3,62.25,NA,42.85714286,0.578212291,0.6067,"Fv/Fm",1,NA,0.021787709,NA,0.01257914,3,0.8,0.018738,-0.930204279,0.738773333
"1883",1883,1899,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",4,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.621787709,"Fv/Fm","productivity","phys","dQ",NA,0.010055866,NA,0.005805757,3,62.25,NA,42.85714286,0.578212291,0.6302,"Fv/Fm",1,NA,0.005027933,NA,0.002902878,3,0.8,0.00794986,0.843274043,0.725925926
"1884",1884,1900,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",5,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,8.089361702,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.598324022,"Fv/Fm","productivity","phys","dQ",NA,0.010055866,NA,0.005805757,3,62.25,NA,42.85714286,0.578212291,0.6117,"Fv/Fm",1,NA,0.006703911,NA,0.003870505,3,0.8,0.008545843,1.255143265,0.797948718
"1885",1885,1901,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",6,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.605027933,"Fv/Fm","productivity","phys","dQ",NA,0.015083799,NA,0.008708635,3,62.25,NA,42.85714286,0.578212291,0.6034,"Fv/Fm",1,NA,0.013407821,NA,0.007741009,3,0.8,0.014270436,-0.093955235,0.667402299
"1886",1886,1902,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",7,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,8.123404255,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.588268156,"Fv/Fm","productivity","phys","dQ",NA,0.003351955,NA,0.001935252,3,62.25,NA,42.85714286,0.578212291,0.605,"Fv/Fm",1,NA,0.011731844,NA,0.006773383,3,0.8,0.008627623,1.55405738,0.867924528
"1887",1887,1903,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LN",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",8,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,8.076595745,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.509497207,"Fv/Fm","productivity","phys","dQ",NA,0.016759777,NA,0.009676261,3,62.25,NA,42.85714286,0.578212291,0.5464,"Fv/Fm",1,NA,0.015083799,NA,0.008708635,3,0.8,0.015943825,1.850070926,0.951896869
"1888",1888,1904,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",1,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.516201117,"Fv/Fm","productivity","phys","dQ",NA,0.043575419,NA,0.02515828,3,62.25,NA,42.85714286,0.578212291,0.5413,"Fv/Fm",1,NA,0.020111732,NA,0.011611514,3,0.8,0.033935961,0.592637758,0.695934959
"1889",1889,1905,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",2,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,7.70212766,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.574860335,"Fv/Fm","productivity","phys","dQ",NA,0.013407821,NA,0.007741009,3,62.25,NA,42.85714286,0.578212291,0.5715,"Fv/Fm",1,NA,0.015083799,NA,0.008708635,3,0.8,0.014270436,-0.18791047,0.669609195
"1890",1890,1906,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",3,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.621787709,"Fv/Fm","productivity","phys","dQ",NA,0.008379888,NA,0.004838131,3,62.25,NA,42.85714286,0.578212291,0.6184,"Fv/Fm",1,NA,0.018435754,NA,0.010643888,3,0.8,0.014319559,-0.187265836,0.669589041
"1891",1891,1907,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",4,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.611731844,"Fv/Fm","productivity","phys","dQ",NA,0.015083799,NA,0.008708635,3,62.25,NA,42.85714286,0.578212291,0.6268,"Fv/Fm",1,NA,0.008379888,NA,0.004838131,3,0.8,0.012201301,0.98899606,0.748176101
"1892",1892,1908,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",5,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,7.659574468,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.596648045,"Fv/Fm","productivity","phys","dQ",NA,0.018435754,NA,0.010643888,3,62.25,NA,42.85714286,0.578212291,0.605,"Fv/Fm",1,NA,0.011731844,NA,0.006773383,3,0.8,0.01545175,0.433860916,0.682352941
"1893",1893,1909,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",6,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.608379888,"Fv/Fm","productivity","phys","dQ",NA,0.020111732,NA,0.011611514,3,62.25,NA,42.85714286,0.578212291,0.6134,"Fv/Fm",1,NA,0.006703911,NA,0.003870505,3,0.8,0.0149904,0.268328157,0.672666667
"1894",1894,1910,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",7,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,7.672340426,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.6,"Fv/Fm","productivity","phys","dQ",NA,0.011731844,NA,0.006773383,3,62.25,NA,42.85714286,0.578212291,0.6117,"Fv/Fm",1,NA,0.005027933,NA,0.002902878,3,0.8,0.009025416,1.039893894,0.756781609
"1895",1895,1911,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 1","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",8,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,7.659574468,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,0.578212291,0.522905028,"Fv/Fm","productivity","phys","dQ",NA,0.021787709,NA,0.01257914,3,62.25,NA,42.85714286,0.578212291,0.5531,"Fv/Fm",1,NA,0.013407821,NA,0.007741009,3,0.8,0.018089693,1.334134237,0.814992847
"1896",1896,1912,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LC",NA,"Fig. 3","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",4,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,43.46590909,"Chl a NPP","biom","biom","SS",NA,7.670454545,NA,4.428538997,3,62.25,NA,42.85714286,NA,43.75,"Chl a NPP",2,NA,5.965909091,NA,3.44441922,3,0.8,6.871242399,0.033075929,0.666757835
"1897",1897,1913,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LC",NA,"Fig. 3","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",8,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,8.076595745,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,38.35227273,"Chl a NPP","biom","biom","SS",NA,1.704545455,NA,0.984119777,3,62.25,NA,42.85714286,NA,38.0682,"Chl a NPP",2,NA,2.556818182,NA,1.476179666,3,0.8,2.172877634,-0.104595272,0.667578348
"1898",1898,1914,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 3","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",4,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,44.88636364,"Chl a NPP","biom","biom","SS",NA,5.965909091,NA,3.44441922,3,62.25,NA,42.85714286,NA,37.7841,"Chl a NPP",2,NA,5.113636364,NA,2.952359331,3,0.8,5.556138414,-1.022619985,0.753812636
"1899",1899,1915,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Fig. 3","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",8,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,7.659574468,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,39.20454545,"Chl a NPP","biom","biom","SS",NA,3.977272727,NA,2.29627948,3,62.25,NA,42.85714286,NA,42.3295,"Chl a NPP",2,NA,5.965909091,NA,3.44441922,3,0.8,5.070047812,0.493091997,0.68692831
"1900",1900,1916,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LC",NA,"Table 2","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",4,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,1.32,"net growth rate (d-1","biom","biom","SS",NA,0.04,NA,0.023094011,3,62.25,NA,42.85714286,NA,1.33,"net growth rate (d-1",2,NA,0.1,NA,0.023094011,3,0.8,0.076157731,0.105045146,0.667586207
"1901",1901,1917,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"LC",NA,"Table 2","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",8,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,8.076595745,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,1.06,"net growth rate (d-1","biom","biom","SS",NA,0.09,NA,0.051961524,3,62.25,NA,42.85714286,NA,1.1,"net growth rate (d-1",2,NA,0.07,NA,0.023094011,3,0.8,0.080622577,0.396911151,0.679794872
"1902",1902,1918,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Table 2","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",4,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,NA,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,1.27,"net growth rate (d-1","biom","biom","SS",NA,0.07,NA,0.040414519,3,62.25,NA,42.85714286,NA,1.22,"net growth rate (d-1",2,NA,0.04,NA,0.023094011,3,0.8,0.057008771,-0.701646415,0.707692308
"1903",1903,1919,"956","Hoppe, CJM; Schuback, N; Semeniuk, D; Giesbrecht, K; Mol, J; Thomas, H; Maldonado, MT; Rost, B; Varela, DE; Tortell, PD",2018,"Resistance of Arctic phytoplankton to ocean acidification and enhanced irradiance","POLAR BIOLOGY",1,"HC",NA,"Table 2","summer","2016","Lab","coastal",71.40545,-68.60095,"Baffin Bay","total phytoplankton","phytoplankton",8,"microcosm","culture flask",8,NA,"No","pCO2","reduced light",NA,415,NA,NA,7.659574468,NA,NA,2.5,20,NA,NA,30,3,145.25,NA,100,NA,1.07,"net growth rate (d-1","biom","biom","SS",NA,0.14,NA,0.080829038,3,62.25,NA,42.85714286,NA,1.03,"net growth rate (d-1",2,NA,0.12,NA,0.023094011,3,0.8,0.130384048,-0.245428796,0.671686275
"1904",1904,1920,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,3e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1905",1905,1921,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,3e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1906",1906,1922,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,3e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1907",1907,1923,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,4e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1908",1908,1924,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,1e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1909",1909,1925,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,0.0012,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1910",1910,1926,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,0.0013,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1911",1911,1927,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,0.0011,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1912",1912,1928,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,9e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1913",1913,1929,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,8e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1914",1914,1930,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,0.002,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1915",1915,1931,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,0.0019,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1916",1916,1932,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,0.0017,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1917",1917,1933,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,0.0012,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1918",1918,1934,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,0.0011,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1919",1919,1935,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,0.0029,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1920",1920,1936,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,0.0023,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1921",1921,1937,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,0.0017,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1922",1922,1938,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,0.0015,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1923",1923,1939,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,0.0013,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1924",1924,1940,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,0.0038,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1925",1925,1941,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,0.0024,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1926",1926,1942,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,0.002,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1927",1927,1943,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,0.0013,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1928",1928,1944,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,0.0014,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1929",1929,1945,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,0.0044,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1930",1930,1946,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,0.0025,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1931",1931,1947,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,0.002,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1932",1932,1948,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,0.0016,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1933",1933,1949,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,0.0015,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1934",1934,1950,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,0.0051,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1935",1935,1951,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,0.0028,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1936",1936,1952,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,0.0023,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1937",1937,1953,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,0.0016,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1938",1938,1954,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,0.0015,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1939",1939,1955,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.006104046,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,0.0056,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1940",1940,1956,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.003398844,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,0.0031,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1941",1941,1957,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.002531792,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,0.0024,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1942",1942,1958,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001699422,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,0.0018,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1943",1943,1959,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.001803468,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,0.0017,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1944",1944,1960,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,2500.7583,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1945",1945,1961,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,1673.5757,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1946",1946,1962,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,1342.4498,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1947",1947,1963,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,1507.3808,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1948",1948,1964,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,845.7611,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1949",1949,1965,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,5961.7815,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1950",1950,1966,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,3809.4636,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1951",1951,1967,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,3146.5801,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1952",1952,1968,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,2649.8913,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1953",1953,1969,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,19,NA,19,NA,1988.2716,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1954",1954,1970,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,9587.1038,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1955",1955,1971,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,5283.0999,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1956",1956,1972,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,4289.7225,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1957",1957,1973,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,3626.8389,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1958",1958,1974,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,29,NA,29,NA,3130.1501,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1959",1959,1975,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,12714.4735,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1960",1960,1976,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,6920.4034,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1961",1961,1977,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,5927.0259,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1962",1962,1978,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,4601.8907,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1963",1963,1979,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,40,NA,40,NA,3940.271,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1964",1964,1980,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,16007.4061,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1965",1965,1981,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,8557.7069,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1966",1966,1982,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,7067.6407,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1967",1967,1983,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,5908.0683,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1968",1968,1984,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,50,NA,50,NA,4749.7599,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1969",1969,1985,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,19632.0965,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1970",1970,1986,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,10194.3784,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1971",1971,1987,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,8207.6235,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1972",1972,1988,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,6551.9943,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1973",1973,1989,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,62,NA,62,NA,6055.3056,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1974",1974,1990,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,23420.454,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1975",1975,1991,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,12161.5439,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1976",1976,1992,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,9678.7321,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1977",1977,1993,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,7691.3452,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1978",1978,1994,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,74,NA,74,NA,6201.279,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1979",1979,1995,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"0",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,31489.43431,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,27868.5355,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1980",1980,1996,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"30",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,15926.5204,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,13961.2507,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1981",1981,1997,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"50",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,12449.69921,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,11312.2441,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1982",1982,1998,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"80",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,9635.12967,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,8828.8004,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1983",1983,1999,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"100",NA,"Fig. 5",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","DCMU","gradient",NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,8309.994439,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,87,NA,87,NA,7669.86,"Photosynthetic electron transport rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1984",1984,2000,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,4e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1985",1985,2001,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,2e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1986",1986,2002,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,1e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1987",1987,2003,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,1e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1988",1988,2004,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,-1e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1989",1989,2005,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,-1e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1990",1990,2006,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,8e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1991",1991,2007,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1992",1992,2008,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,8e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1993",1993,2009,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,7e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1994",1994,2010,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,5e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1995",1995,2011,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,4e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1996",1996,2012,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0014,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1997",1997,2013,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0018,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1998",1998,2014,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0016,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"1999",1999,2015,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0011,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2000",2000,2016,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0011,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2001",2001,2017,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9e-04,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2002",2002,2018,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0021,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2003",2003,2019,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0028,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2004",2004,2020,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0027,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2005",2005,2021,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0022,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2006",2006,2022,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0019,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2007",2007,2023,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0017,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2008",2008,2024,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0026,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2009",2009,2025,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0036,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2010",2010,2026,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0035,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2011",2011,2027,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.003,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2012",2012,2028,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0026,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2013",2013,2029,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0024,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2014",2014,2030,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0031,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2015",2015,2031,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0043,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2016",2016,2032,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0045,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2017",2017,2033,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0039,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2018",2018,2034,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0032,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2019",2019,2035,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0032,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2020",2020,2036,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0037,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2021",2021,2037,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0051,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2022",2022,2038,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0052,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2023",2023,2039,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0048,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2024",2024,2040,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0038,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2025",2025,2041,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0039,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2026",2026,2042,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,0.004377358,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.004,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2027",2027,2043,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,0.006301887,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0057,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2028",2028,2044,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,0.006754717,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0062,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2029",2029,2045,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,0.006188679,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0055,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2030",2030,2046,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,0.004603774,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0042,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2031",2031,2047,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,0.004867925,"Photosynthetic oxygen evolution rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,0.0043,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2032",2032,2048,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,2573.4167,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2033",2033,2049,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,2762.8553,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2034",2034,2050,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,3326.0113,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2035",2035,2051,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,3324.5371,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2036",2036,2052,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,2762.1182,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2037",2037,2053,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,2949.3454,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2038",2038,2054,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,6163.1678,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2039",2039,2055,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,6351.8693,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2040",2040,2056,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,6916.4996,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2041",2041,2057,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,6727.061,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2042",2042,2058,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,6165.3792,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2043",2043,2059,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,5600.0118,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2044",2044,2060,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9377.7273,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2045",2045,2061,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9565.6917,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2046",2046,2062,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,10319.0235,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2047",2047,2063,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9942.3576,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2048",2048,2064,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9190.5001,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2049",2049,2065,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,9755.1303,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2050",2050,2066,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,12969.6898,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2051",2051,2067,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,13346.3557,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2052",2052,2068,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,14286.9147,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2053",2053,2069,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,13910.2489,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2054",2054,2070,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,12406.5338,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2055",2055,2071,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,12782.4626,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2056",2056,2072,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,16563.1265,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2057",2057,2073,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,17127.0197,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2058",2058,2074,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,18629.9976,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2059",2059,2075,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,17878.1401,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2060",2060,2076,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,15810.5319,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2061",2061,2077,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,16186.4607,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2062",2062,2078,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,19966.3875,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2063",2063,2079,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,20717.508,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2064",2064,2080,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,22973.8177,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2065",2065,2081,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,21845.2943,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2066",2066,2082,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,19402.4944,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2067",2067,2083,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,20341.5792,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2068",2068,2084,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,23183.8955,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2069",2069,2085,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,24688.3477,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2070",2070,2086,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,27131.8847,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2071",2071,2087,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,26003.3612,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2072",2072,2088,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,22996.6682,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2073",2073,2089,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,23748.5258,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2074",2074,2090,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"16",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,16,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,27344.911,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2075",2075,2091,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"32",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,32,NA,NA,NA,0,100,NA,100,NA,33008.16724,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,29035.1162,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2076",2076,2092,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"64",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,64,NA,NA,NA,0,100,NA,100,NA,36954.68216,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,31855.319,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2077",2077,2093,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"128",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,128,NA,NA,NA,0,100,NA,100,NA,35263.00271,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,30915.4971,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2078",2078,2094,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"228",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,228,NA,NA,NA,0,100,NA,100,NA,30939.82191,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,27156.2095,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2079",2079,2095,"962","Yin, GF; Zhao, NJ; Shi, CY; Chen, S; Qin, ZS; Zhang, XL; Yan, RF; Gan, TT; Liu, JG; Liu, WQ",2018,"Phytoplankton photosynthetic rate measurement using tunable pulsed light induced fluorescence kinetics","Opt. Express 26",1,"512",NA,"Fig. 7",NA,NA,NA,NA,NA,NA,NA,"Chlorella pyrenoidosa ","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","nut","gradient",NA,NA,NA,NA,NA,NA,NA,NA,512,NA,NA,NA,0,100,NA,100,NA,31691.67944,"Photosynthetic electron transport rate curves ","productivity","phys","dQ",NA,NA,NA,NA,3,9,NA,9,NA,27531.4011,"Photosynthetic oxygen evolution rate curves ",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2080",2080,2096,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.606382979,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.127659574,NA,0.015258238,3,70,NA,15.55555556,NA,0.766,"Chl a (ng per cell)",1,NA,0.159574468,NA,0.092130362,3,0.8,0.144500827,0.883452209,0.731707317
"2081",2081,2097,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.893617021,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.223404255,NA,0.026701916,3,70,NA,15.55555556,NA,1.2766,"Chl a (ng per cell)",1,NA,0.191489362,NA,0.110556435,3,0.8,0.208059651,1.472572779,0.847372549
"2082",2082,2098,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.074468085,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.223404255,NA,0.026701916,3,70,NA,15.55555556,NA,4.9468,"Chl a (ng per cell)",1,NA,0.223404255,NA,0.128982507,3,0.8,0.223404255,10.28571429,9.482993197
"2083",2083,2099,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.606382979,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.127659574,NA,0.011418219,3,125,NA,27.77777778,NA,0.766,"Chl a (ng per cell)",1,NA,0.159574468,NA,0.092130362,3,0.8,0.144500827,0.883452209,0.731707317
"2084",2084,2100,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.893617021,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.223404255,NA,0.019981884,3,125,NA,27.77777778,NA,1.2447,"Chl a (ng per cell)",1,NA,0.191489362,NA,0.110556435,3,0.8,0.208059651,1.34985838,0.818509804
"2085",2085,2101,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.074468085,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.223404255,NA,0.019981884,3,125,NA,27.77777778,NA,3.9574,"Chl a (ng per cell)",1,NA,0.191489362,NA,0.110556435,3,0.8,0.208059651,7.240149495,5.034980392
"2086",2086,2102,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.606382979,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.127659574,NA,0.008510638,3,225,NA,50,NA,0.6702,"Chl a (ng per cell)",1,NA,0.159574468,NA,0.092130362,3,0.8,0.144500827,0.353380883,0.677073171
"2087",2087,2103,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.893617021,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.223404255,NA,0.014893617,3,225,NA,50,NA,1.117,"Chl a (ng per cell)",1,NA,0.223404255,NA,0.128982507,3,0.8,0.223404255,0.8,0.72
"2088",2088,2104,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.074468085,"Chl a (ng per cell)","cellular content","phys","Q",NA,0.223404255,NA,0.014893617,3,225,NA,50,NA,2.8085,"Chl a (ng per cell)",1,NA,0.191489362,NA,0.110556435,3,0.8,0.208059651,2.822431159,1.330509804
"2089",2089,2105,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,6.007936508,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.285714286,NA,0.034149389,3,70,NA,15.55555556,NA,7.7698,"Chl a (10^7 ng µm^3)",2,NA,0.285714286,NA,0.16495722,3,0.8,0.285714286,4.933333333,2.694814815
"2090",2090,2106,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.96031746,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.333333333,NA,0.039840954,3,70,NA,15.55555556,NA,4.627,"Chl a (10^7 ng µm^3)",2,NA,0.380952381,NA,0.21994296,3,0.8,0.357935628,3.725064589,1.82300885
"2091",2091,2107,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.960695389,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.380574452,NA,0.045487347,3,70,NA,15.55555556,NA,6.6746,"Chl a (10^7 ng µm^3)",2,NA,0.380952381,NA,0.21994296,3,0.8,0.380763463,7.803075962,5.740666206
"2092",2092,2108,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,6.007936508,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.285714286,NA,0.025555063,3,125,NA,27.77777778,NA,7.7381,"Chl a (10^7 ng µm^3)",2,NA,0.285714286,NA,0.16495722,3,0.8,0.285714286,4.844444444,2.622386831
"2093",2093,2109,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.96031746,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.333333333,NA,0.02981424,3,125,NA,27.77777778,NA,4.5952,"Chl a (10^7 ng µm^3)",2,NA,0.428571429,NA,0.24743583,3,0.8,0.383917036,3.40682071,1.633868946
"2094",2094,2110,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.960695389,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.380574452,NA,0.034039614,3,125,NA,27.77777778,NA,5.8333,"Chl a (10^7 ng µm^3)",2,NA,0.380952381,NA,0.21994296,3,0.8,0.380763463,6.035532756,3.702304637
"2095",2095,2111,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,6.007936508,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.285714286,NA,0.019047619,3,225,NA,50,NA,6.8968,"Chl a (10^7 ng µm^3)",2,NA,0.238095238,NA,0.13746435,3,0.8,0.262984786,2.704000948,1.275968427
"2096",2096,2112,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.96031746,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.333333333,NA,0.022222222,3,225,NA,50,NA,3.4206,"Chl a (10^7 ng µm^3)",2,NA,0.380952381,NA,0.21994296,3,0.8,0.357935628,1.028827363,0.754873812
"2097",2097,2113,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 1",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,2.960695389,"Chl a (10^7 ng µm^3)","biom","biom","SS",NA,0.380574452,NA,0.02537163,3,225,NA,50,NA,4.2778,"Chl a (10^7 ng µm^3)",2,NA,0.333333333,NA,0.19245009,3,0.8,0.357734556,2.945384767,1.389607619
"2098",2098,2114,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,1.166315789,"growth rate","biom","biom","dSS",NA,0.067368421,NA,0.008052066,3,70,NA,15.55555556,NA,0.6105,"growth rate",2,NA,0.042105263,NA,0.024309485,3,0.8,0.056175428,-7.915054636,5.887340824
"2099",2099,2115,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,1.435789474,"growth rate","biom","biom","dSS",NA,0.067368421,NA,0.008052066,3,70,NA,15.55555556,NA,0.5684,"growth rate",2,NA,0.050526316,NA,0.029171382,3,0.8,0.059545834,-11.65311975,11.98293333
"2100",2100,2116,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.762105263,"growth rate","biom","biom","dSS",NA,0.058947368,NA,0.007045558,3,70,NA,15.55555556,NA,0.5095,"growth rate",2,NA,0.042105263,NA,0.024309485,3,0.8,0.051223263,-3.945575695,1.963963964
"2101",2101,2117,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,1.166315789,"growth rate","biom","biom","dSS",NA,0.067368421,NA,0.006025615,3,125,NA,27.77777778,NA,0.8632,"growth rate",2,NA,0.042105263,NA,0.024309485,3,0.8,0.056175428,-4.317302529,2.219925094
"2102",2102,2118,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,1.435789474,"growth rate","biom","biom","dSS",NA,0.067368421,NA,0.006025615,3,125,NA,27.77777778,NA,0.7705,"growth rate",2,NA,0.033684211,NA,0.019447588,3,0.8,0.053259413,-9.992797406,8.988
"2103",2103,2119,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.762105263,"growth rate","biom","biom","dSS",NA,0.058947368,NA,0.005272413,3,125,NA,27.77777778,NA,0.6021,"growth rate",2,NA,0.058947368,NA,0.034033279,3,0.8,0.058947368,-2.171428571,1.059591837
"2104",2104,2120,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,1.166315789,"growth rate","biom","biom","dSS",NA,0.067368421,NA,0.004491228,3,225,NA,50,NA,1.0653,"growth rate",2,NA,0.050526316,NA,0.029171382,3,0.8,0.059545834,-1.35764502,0.820266667
"2105",2105,2121,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,1.435789474,"growth rate","biom","biom","dSS",NA,0.067368421,NA,0.004491228,3,225,NA,50,NA,1.1495,"growth rate",2,NA,0.050526316,NA,0.029171382,3,0.8,0.059545834,-3.84666089,1.899733333
"2106",2106,2122,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 7a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.762105263,"growth rate","biom","biom","dSS",NA,0.058947368,NA,0.003929825,3,225,NA,50,NA,0.8463,"growth rate",2,NA,0.058947368,NA,0.034033279,3,0.8,0.058947368,1.142857143,0.775510204
"2107",2107,2123,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.02317757,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002990654,NA,0.000357452,3,70,NA,15.55555556,NA,0.0381,"quantum yields of oxygen",1,NA,0.001495327,NA,0.000863328,3,0.8,0.00236432,5.059644256,2.8
"2108",2108,2124,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.014205607,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002990654,NA,0.000357452,3,70,NA,15.55555556,NA,0.065,"quantum yields of oxygen",1,NA,0.008971963,NA,0.005179965,3,0.8,0.006687306,6.082104899,3.749333333
"2109",2109,2125,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.015700935,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002242991,NA,0.000268089,3,70,NA,15.55555556,NA,0.0493,"quantum yields of oxygen",1,NA,0.002242991,NA,0.001294991,3,0.8,0.002242991,12,12.66666667
"2110",2110,2126,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.02317757,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002990654,NA,0.000267492,3,125,NA,27.77777778,NA,0.0374,"quantum yields of oxygen",1,NA,0.002990654,NA,0.001726655,3,0.8,0.002990654,3.8,1.87
"2111",2111,2127,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.014205607,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002990654,NA,0.000267492,3,125,NA,27.77777778,NA,0.0419,"quantum yields of oxygen",1,NA,0.005981308,NA,0.00345331,3,0.8,0.004728639,4.680170937,2.492
"2112",2112,2128,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.015700935,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002242991,NA,0.000200619,3,125,NA,27.77777778,NA,0.0516,"quantum yields of oxygen",1,NA,0.01046729,NA,0.006043293,3,0.8,0.007569517,3.792881651,1.865495935
"2113",2113,2129,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.02317757,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002990654,NA,0.000199377,3,225,NA,50,NA,0.0217,"quantum yields of oxygen",1,NA,0.003738318,NA,0.002158319,3,0.8,0.003385191,-0.353380883,0.677073171
"2114",2114,2130,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.014205607,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002990654,NA,0.000199377,3,225,NA,50,NA,0.0277,"quantum yields of oxygen",1,NA,0.004485981,NA,0.002589983,3,0.8,0.003812351,2.824072346,1.331282051
"2115",2115,2131,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 6a",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.015700935,"quantum yields of oxygen","quantum yield","phys","dQ",NA,0.002242991,NA,0.000149533,3,225,NA,50,NA,0.0194,"quantum yields of oxygen",1,NA,0.002990654,NA,0.001726655,3,0.8,0.00264339,1.13137085,0.773333333
"2116",2116,2132,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.017894737,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.001403509,NA,0.000167751,3,70,NA,15.55555556,NA,0.0179,"quantum yields of carbon",1,NA,0.001403509,NA,0.000810316,3,0.8,0.001403509,0,0.666666667
"2117",2117,2133,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.02,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.004561404,NA,0.000545192,3,70,NA,15.55555556,NA,0.026,"quantum yields of carbon",1,NA,0.002105263,NA,0.001215474,3,0.8,0.003552361,1.343312251,0.81704065
"2118",2118,2134,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.023859649,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.001754386,NA,0.000209689,3,70,NA,15.55555556,NA,0.0105,"quantum yields of carbon",1,NA,0.002807018,NA,0.001620632,3,0.8,0.002340643,-4.557152669,2.397303371
"2119",2119,2135,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.017894737,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.001403509,NA,0.000125534,3,125,NA,27.77777778,NA,0.0161,"quantum yields of carbon",1,NA,0.003157895,NA,0.001823211,3,0.8,0.002443577,-0.574366527,0.694158076
"2120",2120,2136,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.02,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.004561404,NA,0.000407984,3,125,NA,27.77777778,NA,0.0112,"quantum yields of carbon",1,NA,0.003157895,NA,0.001823211,3,0.8,0.003922926,-1.788854382,0.933333333
"2121",2121,2137,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.023859649,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.001754386,NA,0.000156917,3,125,NA,27.77777778,NA,0.0218,"quantum yields of carbon",1,NA,0.001754386,NA,0.001012895,3,0.8,0.001754386,-0.96,0.743466667
"2122",2122,2138,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"120",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.017894737,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.001403509,NA,9.35673e-05,3,225,NA,50,NA,0.0126,"quantum yields of carbon",1,NA,0.00245614,NA,0.001418053,3,0.8,0.002000308,-2.104939246,1.035897436
"2123",2123,2139,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"200",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.02,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.004561404,NA,0.000304094,3,225,NA,50,NA,0.0133,"quantum yields of carbon",1,NA,0.001754386,NA,0.001012895,3,0.8,0.00345574,-1.543326171,0.865154639
"2124",2124,2140,"975","Yan, D; Beardall, J; Gao, KS",2018,"Variation in cell size of the diatom Coscinodiscus granii influences photosynthetic performance and growth","Photosynthesis Research",1,"280",NA,"Fig. 6b",NA,"2016","Lab","coastal",NA,NA,"Wuyuan Bay, Xiamen","Coscinodiscus granii","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","none","gradient","12",450,NA,20,8.1,NA,NA,NA,NA,NA,NA,NA,0,450,NA,100,NA,0.023859649,"quantum yields of carbon","quantum yield","phys","dQ",NA,0.001754386,NA,0.000116959,3,225,NA,50,NA,0.0309,"quantum yields of carbon",1,NA,0.008070175,NA,0.004659318,3,0.8,0.00583976,0.961346829,0.74368231
"2125",2125,2141,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulva lactuca","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,10,NA,NA,NA,1,29,NA,100,NA,0.378205128,"Fv/Fm","productivity","phys","dQ",NA,0.032051282,NA,0.013084881,6,4,NA,13.79310345,NA,0.6795,"Fv/Fm",1,NA,0.025641026,NA,0.010467905,6,0.923076923,0.02902367,9.58205857,4.158993602
"2126",2126,2142,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulva lactuca","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,160,NA,NA,NA,1,29,NA,100,NA,0.602564103,"Fv/Fm","productivity","phys","dQ",NA,0.064102564,NA,0.026169762,6,4,NA,13.79310345,NA,0.7821,"Fv/Fm",1,NA,0.019230769,NA,0.007850929,6,0.923076923,0.047323151,3.501044847,0.844054793
"2127",2127,2143,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulvaria obscura","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,10,NA,NA,NA,1,29,NA,100,NA,0.224358974,"Fv/Fm","productivity","phys","dQ",NA,0.224358974,NA,0.091594168,6,4,NA,13.79310345,NA,0.4487,"Fv/Fm",1,NA,0.038461538,NA,0.015701857,6,0.923076923,0.160959994,1.286658794,0.402312119
"2128",2128,2144,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,NA,NA,"Fig. 2",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulvaria obscura","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,160,NA,NA,NA,1,29,NA,100,NA,0.583333333,"Fv/Fm","productivity","phys","dQ",NA,0.583333333,NA,0.238144836,6,4,NA,13.79310345,NA,0.7372,"Fv/Fm",1,NA,0.019230769,NA,0.007850929,6,0.923076923,0.412703041,0.344101739,0.338266917
"2129",2129,2145,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"mass",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulva lactuca","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,10,NA,NA,NA,1,29,NA,100,NA,8.193103448,"growth rate","biom","biom","dSS",NA,0.331034483,NA,0.135144262,6,4,NA,13.79310345,NA,5.2966,"growth rate",2,NA,0.331034483,NA,0.135144262,6,0.923076923,0.331034483,-8.076923077,3.0515286
"2130",2130,2146,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"mass",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulva lactuca","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,160,NA,NA,NA,1,29,NA,100,NA,13.48965517,"growth rate","biom","biom","dSS",NA,0.827586207,NA,0.337860654,6,4,NA,13.79310345,NA,9.269,"growth rate",2,NA,0.413793103,NA,0.168930327,6,0.923076923,0.654264343,-5.954812086,1.810824458
"2131",2131,2147,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"surface area",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulva lactuca","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,10,NA,NA,NA,1,29,NA,100,NA,8.35862069,"growth rate","biom","biom","dSS",NA,0.496551724,NA,0.202716393,6,4,NA,13.79310345,NA,5.8759,"growth rate",2,NA,0.413793103,NA,0.168930327,6,0.923076923,0.457049421,-5.014287473,1.380961619
"2132",2132,2148,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"surface area",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulva lactuca","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,160,NA,NA,NA,1,29,NA,100,NA,13.90344828,"growth rate","biom","biom","dSS",NA,0.827586207,NA,0.337860654,6,4,NA,13.79310345,NA,9.269,"growth rate",2,NA,0.496551724,NA,0.202716393,6,0.923076923,0.682445069,-6.268613078,1.970646247
"2133",2133,2149,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"mass",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulvaria obscura","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,10,NA,NA,NA,1,29,NA,100,NA,3.543956044,"growth rate","biom","biom","dSS",NA,0.576923077,NA,0.23552786,6,4,NA,13.79310345,NA,5.0275,"growth rate",2,NA,0.824175824,NA,0.336468371,6,0.923076923,0.711374032,1.925006776,0.487735462
"2134",2134,2150,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"mass",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulvaria obscura","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,160,NA,NA,NA,1,29,NA,100,NA,9.56043956,"growth rate","biom","biom","dSS",NA,0.989010989,NA,0.403762046,6,4,NA,13.79310345,NA,8.3242,"growth rate",2,NA,0.576923077,NA,0.23552786,6,0.923076923,0.809624287,-1.40950135,0.416112252
"2135",2135,2151,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"surface area",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulvaria obscura","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,10,NA,NA,NA,1,29,NA,100,NA,4.697802198,"growth rate","biom","biom","dSS",NA,0.741758242,NA,0.302821534,6,4,NA,13.79310345,NA,6.0989,"growth rate",2,NA,0.412087912,NA,0.168234186,6,0.923076923,0.600009057,2.155504234,0.526924938
"2136",2136,2152,"985","Van Alstyne, KL",2018,"Seawater nitrogen concentration and light independently alter performance, growth, and resource allocation in the bloom-forming seaweeds Ulva lactuca and Ulvaria obscura (Chlorophyta)","Harmful ALGAE",1,"surface area",NA,"Fig. 3",NA,NA,"Lab","coastal",NA,NA,"Ship Harbor, Washington","Ulvaria obscura","seaweed",14,"microcosm","culture flask",0.2,NA,"No","nut","shading","16",NA,NA,12,NA,NA,NA,NA,160,NA,NA,NA,1,29,NA,100,NA,8.818681319,"growth rate","biom","biom","dSS",NA,0.824175824,NA,0.336468371,6,4,NA,13.79310345,NA,9.2308,"growth rate",2,NA,0.494505495,NA,0.201881023,6,0.923076923,0.679632795,0.559697596,0.346385892
"2137",2137,2153,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,40,NA,4,NA,15.873,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.761904762,-3.466666667,1.668148149
"2138",2138,2154,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,44.44444444,NA,25.66001196,3,40,NA,4,NA,12.6984,"net photosynthesis (cell)",1,NA,42.85714286,NA,24.74358297,3,0.8,43.65800806,-0.523549834,0.689508702
"2139",2139,2155,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.761904762,NA,-2.749286996,3,40,NA,4,NA,11.1111,"net photosynthesis (cell)",1,NA,1.587301587,NA,0.916428999,3,0.8,3.54931425,-5.724334023,3.397333334
"2140",2140,2156,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,52.38095238,NA,30.24215696,3,40,NA,4,NA,9.5238,"net photosynthesis (cell)",1,NA,-1.587301587,NA,-0.916428999,3,0.8,37.05592867,-0.685364699,0.705810398
"2141",2141,2157,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,80,NA,8,NA,23.8095,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.611958581,-1.81019336,0.939733333
"2142",2142,2158,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,44.44444444,NA,25.66001196,3,80,NA,8,NA,20.6349,"net photosynthesis (cell)",1,NA,57.14285714,NA,32.99144395,3,0.8,51.18893808,-0.32249031,0.675333333
"2143",2143,2159,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.761904762,NA,-2.749286996,3,80,NA,8,NA,15.873,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.611958581,-2.941564211,1.387733334
"2144",2144,2160,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,52.38095238,NA,30.24215696,3,80,NA,8,NA,17.4603,"net photosynthesis (cell)",1,NA,-6.349206349,NA,-3.665715995,3,0.8,37.31002944,-0.510522756,0.688386124
"2145",2145,2161,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,160,NA,16,NA,25.3968,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.611958581,-1.58391919,0.875733333
"2146",2146,2162,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,44.44444444,NA,25.66001196,3,160,NA,16,NA,28.5714,"net photosynthesis (cell)",1,NA,73.01587302,NA,42.15573394,3,0.8,60.4426437,-0.168072234,0.66902069
"2147",2147,2163,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.761904762,NA,-2.749286996,3,160,NA,16,NA,23.8095,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.611958581,-1.81019336,0.939733333
"2148",2148,2164,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,52.38095238,NA,30.24215696,3,160,NA,16,NA,28.5714,"net photosynthesis (cell)",1,NA,-4.761904762,NA,-2.749286996,3,0.8,37.19166512,-0.273145344,0.672884032
"2149",2149,2165,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,320,NA,32,NA,30.1587,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.611958581,-0.90509668,0.734933333
"2150",2150,2166,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,44.44444444,NA,25.66001196,3,320,NA,32,NA,39.6825,"net photosynthesis (cell)",1,NA,79.36507937,NA,45.82144994,3,0.8,64.3199987,-0.019742557,0.666699147
"2151",2151,2167,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.761904762,NA,-2.749286996,3,320,NA,32,NA,28.5714,"net photosynthesis (cell)",1,NA,7.936507937,NA,4.582144994,3,0.8,6.544612104,-0.970142501,0.745098039
"2152",2152,2168,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,52.38095238,NA,30.24215696,3,320,NA,32,NA,38.0952,"net photosynthesis (cell)",1,NA,0,NA,0,3,0.8,37.03892663,-0.06856793,0.667058463
"2153",2153,2169,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,640,NA,64,NA,33.3333,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.761904762,-0.533333334,0.69037037
"2154",2154,2170,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,44.44444444,NA,25.66001196,3,640,NA,64,NA,39.6825,"net photosynthesis (cell)",1,NA,80.95238095,NA,46.73787893,3,0.8,65.30159502,-0.019445793,0.666698178
"2155",2155,2171,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.761904762,NA,-2.749286996,3,640,NA,64,NA,34.9206,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.761904762,-0.266666667,0.672592593
"2156",2156,2172,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,52.38095238,NA,30.24215696,3,640,NA,64,NA,39.6825,"net photosynthesis (cell)",1,NA,1.587301587,NA,0.916428999,3,0.8,37.05592867,-0.034268235,0.666764526
"2157",2157,2173,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,800,NA,80,NA,34.9206,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,4.046840884,-0.313785817,0.674871795
"2158",2158,2174,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,44.44444444,NA,25.66001196,3,800,NA,80,NA,41.2698,"net photosynthesis (cell)",1,NA,82.53968254,NA,47.65430793,3,0.8,66.28766037,0,0.666666667
"2159",2159,2175,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,36.50793651,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.761904762,NA,-2.749286996,3,800,NA,80,NA,36.5079,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.761904762,0,0.666666667
"2160",2160,2176,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,41.26984127,"net photosynthesis (cell)","productivity","phys","dQ",NA,52.38095238,NA,30.24215696,3,800,NA,80,NA,41.2698,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,37.19166512,0,0.666666667
"2161",2161,2177,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,30.4,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,40,NA,4,NA,24,"net photosynthesis (cell)",1,NA,6.4,NA,3.695041723,3,0.8,5.059644256,-1.011928851,0.752
"2162",2162,2178,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,100.8,"net photosynthesis (cell)","productivity","phys","dQ",NA,-11.2,NA,-6.466323015,3,40,NA,4,NA,59.2,"net photosynthesis (cell)",1,NA,6.4,NA,3.695041723,3,0.8,9.121403401,-3.64856136,1.776
"2163",2163,2179,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,128,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.8,NA,-2.771281292,3,40,NA,4,NA,12.8,"net photosynthesis (cell)",1,NA,6.4,NA,3.695041723,3,0.8,5.656854249,-16.29174024,22.78506667
"2164",2164,2180,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,139.2,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,40,NA,4,NA,-4.8,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.079215611,-28.24072346,67.12820513
"2165",2165,2181,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,30.4,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,80,NA,8,NA,25.6,"net photosynthesis (cell)",1,NA,6.4,NA,3.695041723,3,0.8,5.059644256,-0.758946638,0.714666667
"2166",2166,2182,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,100.8,"net photosynthesis (cell)","productivity","phys","dQ",NA,-11.2,NA,-6.466323015,3,80,NA,8,NA,81.6,"net photosynthesis (cell)",1,NA,6.4,NA,3.695041723,3,0.8,9.121403401,-1.683951397,0.902974359
"2167",2167,2183,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,128,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.8,NA,-2.771281292,3,80,NA,8,NA,43.2,"net photosynthesis (cell)",1,NA,17.6,NA,10.16136474,3,0.8,12.8996124,-5.259072747,2.971487179
"2168",2168,2184,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,139.2,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,80,NA,8,NA,3.2,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.079215611,-26.67179438,59.94871795
"2169",2169,2185,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,30.4,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,160,NA,16,NA,28.8,"net photosynthesis (cell)",1,NA,6.4,NA,3.695041723,3,0.8,5.059644256,-0.252982213,0.672
"2170",2170,2186,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,100.8,"net photosynthesis (cell)","productivity","phys","dQ",NA,-11.2,NA,-6.466323015,3,160,NA,16,NA,84.8,"net photosynthesis (cell)",1,NA,8,NA,4.618802154,3,0.8,9.732420048,-1.315191898,0.810810811
"2171",2171,2187,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,128,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.8,NA,-2.771281292,3,160,NA,16,NA,68.8,"net photosynthesis (cell)",1,NA,16,NA,9.237604307,3,0.8,11.81185845,-4.009529932,2.006360856
"2172",2172,2188,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,139.2,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,160,NA,16,NA,51.2,"net photosynthesis (cell)",1,NA,52.8,NA,30.48409421,3,0.8,37.40374313,-1.882164567,0.961878622
"2173",2173,2189,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,30.4,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,320,NA,32,NA,30.4,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.079215611,0,0.666666667
"2174",2174,2190,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,100.8,"net photosynthesis (cell)","productivity","phys","dQ",NA,-11.2,NA,-6.466323015,3,320,NA,32,NA,100.8,"net photosynthesis (cell)",1,NA,3.2,NA,1.847520861,3,0.8,8.236504113,0,0.666666667
"2175",2175,2191,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,128,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.8,NA,-2.771281292,3,320,NA,32,NA,92.8,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.8,-5.866666667,3.534814815
"2176",2176,2192,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,139.2,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,320,NA,32,NA,81.6,"net photosynthesis (cell)",1,NA,70.4,NA,40.64545895,3,0.8,49.83171681,-0.924712271,0.737924399
"2177",2177,2193,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,30.4,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,640,NA,64,NA,30.4,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.079215611,0,0.666666667
"2178",2178,2194,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,100.8,"net photosynthesis (cell)","productivity","phys","dQ",NA,-11.2,NA,-6.466323015,3,640,NA,64,NA,102.4,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,8.616263691,0.148556271,0.668505747
"2179",2179,2195,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,128,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.8,NA,-2.771281292,3,640,NA,64,NA,116.8,"net photosynthesis (cell)",1,NA,9.6,NA,5.542562584,3,0.8,7.589466384,-1.18058366,0.782814815
"2180",2180,2196,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,139.2,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,640,NA,64,NA,134.4,"net photosynthesis (cell)",1,NA,75.2,NA,43.41674024,3,0.8,53.22255161,-0.072149867,0.667100467
"2181",2181,2197,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,30.4,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,800,NA,80,NA,32,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.079215611,0.313785816,0.674871795
"2182",2182,2198,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,100.8,"net photosynthesis (cell)","productivity","phys","dQ",NA,-11.2,NA,-6.466323015,3,800,NA,80,NA,100.8,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,8.616263691,0,0.666666667
"2183",2183,2199,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,128,"net photosynthesis (cell)","productivity","phys","dQ",NA,-4.8,NA,-2.771281292,3,800,NA,80,NA,126.4,"net photosynthesis (cell)",1,NA,4.8,NA,2.771281292,3,0.8,4.8,-0.266666667,0.672592593
"2184",2184,2200,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,8,NA,NA,NA,NA,NA,0,1000,NA,100,NA,139.2,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.2,NA,1.847520861,3,800,NA,80,NA,139.2,"net photosynthesis (cell)",1,NA,54.4,NA,31.40785464,3,0.8,38.53310265,0,0.666666667
"2185",2185,2201,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,17.46031746,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,40,NA,4,NA,11.1111,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,4.046840884,-1.255143265,0.797948718
"2186",2186,2202,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,31.74603175,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,40,NA,4,NA,-1.5873,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.046840884,-6.589502141,4.285128206
"2187",2187,2203,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,34.92063492,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,40,NA,4,NA,4.7619,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.019488349,-4.806662043,2.592
"2188",2188,2204,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,38.0952381,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,40,NA,4,NA,7.9365,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,3.174603175,-7.6,5.48
"2189",2189,2205,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,17.46031746,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,80,NA,8,NA,11.1111,"net photosynthesis (cell)",1,NA,9.523809524,NA,5.498573992,3,0.8,7.529232524,-0.674619234,0.704592593
"2190",2190,2206,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,31.74603175,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,80,NA,8,NA,14.2857,"net photosynthesis (cell)",1,NA,1.587301587,NA,0.916428999,3,0.8,2.509744175,-5.565608681,3.248
"2191",2191,2207,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,34.92063492,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,80,NA,8,NA,11.1111,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.046840884,-4.706787243,2.512820513
"2192",2192,2208,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,38.0952381,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,80,NA,8,NA,4.7619,"net photosynthesis (cell)",1,NA,7.936507937,NA,4.582144994,3,0.8,6.04426437,-4.411896144,2.288735632
"2193",2193,2209,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,17.46031746,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,160,NA,16,NA,14.2857,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.611958581,-0.452548339,0.683733333
"2194",2194,2210,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,31.74603175,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,160,NA,16,NA,20.6349,"net photosynthesis (cell)",1,NA,-3.174603175,NA,-1.832857998,3,0.8,3.174603175,-2.800000002,1.320000001
"2195",2195,2211,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,34.92063492,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,160,NA,16,NA,20.6349,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.019488349,-2.276839916,1.098666667
"2196",2196,2212,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"100",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,38.0952381,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,160,NA,16,NA,11.1111,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.046840884,-5.334358877,3.037948719
"2197",2197,2213,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,17.46031746,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,320,NA,32,NA,14.2857,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,4.046840884,-0.627571631,0.699487179
"2198",2198,2214,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,31.74603175,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,320,NA,32,NA,26.9841,"net photosynthesis (cell)",1,NA,7.936507937,NA,4.582144994,3,0.8,6.04426437,-0.630270879,0.699770115
"2199",2199,2215,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,34.92063492,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,320,NA,32,NA,26.9841,"net photosynthesis (cell)",1,NA,7.936507937,NA,4.582144994,3,0.8,6.04426437,-1.050451463,0.75862069
"2200",2200,2216,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,38.0952381,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,320,NA,32,NA,20.6349,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.019488349,-2.782804342,1.312000001
"2201",2201,2217,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,17.46031746,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,640,NA,64,NA,17.4603,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,4.046840884,0,0.666666667
"2202",2202,2218,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"190",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,31.74603175,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,640,NA,64,NA,30.1587,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.019488349,-0.252982213,0.672
"2203",2203,2219,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,34.92063492,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,640,NA,64,NA,30.1587,"net photosynthesis (cell)",1,NA,6.349206349,NA,3.665715995,3,0.8,5.019488349,-0.758946638,0.714666667
"2204",2204,2220,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,38.0952381,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,640,NA,64,NA,33.3333,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.046840884,-0.94135745,0.740512821
"2205",2205,2221,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,17.46031746,"net photosynthesis (cell)","productivity","phys","dQ",NA,4.761904762,NA,2.749286996,3,800,NA,80,NA,15.873,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.761904762,-0.266666667,0.672592593
"2206",2206,2222,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,31.74603175,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,800,NA,80,NA,31.746,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,3.174603175,0,0.666666667
"2207",2207,2223,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,34.92063492,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,800,NA,80,NA,33.3333,"net photosynthesis (cell)",1,NA,4.761904762,NA,2.749286996,3,0.8,4.046840884,-0.313785817,0.674871795
"2208",2208,2224,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"280",NA,"Fig. 7",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,13,NA,NA,NA,NA,NA,0,1000,NA,100,NA,38.0952381,"net photosynthesis (cell)","productivity","phys","dQ",NA,3.174603175,NA,1.832857998,3,800,NA,80,NA,36.5079,"net photosynthesis (cell)",1,NA,3.174603175,NA,1.832857998,3,0.8,3.174603175,-0.400000001,0.68
"2209",2209,2225,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.409090909,"PS capacity","productivity","phys","dQ",NA,0.590909091,NA,0.341161523,3,10,NA,3.571428571,NA,0.2273,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2210",2210,2226,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.545454545,"PS capacity","productivity","phys","dQ",NA,0.454545455,NA,0.262431941,3,10,NA,3.571428571,NA,0.0909,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2211",2211,2227,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.363636364,NA,0.209945553,3,10,NA,3.571428571,NA,0.1364,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2212",2212,2228,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.818181818,"PS capacity","productivity","phys","dQ",NA,0.204545455,NA,0.118094374,3,100,NA,35.71428571,NA,0.3636,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.216207927,-1.681882657,0.902394106
"2213",2213,2229,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.409090909,"PS capacity","productivity","phys","dQ",NA,0.590909091,NA,0.341161523,3,100,NA,35.71428571,NA,0.3636,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.447675355,-0.081227692,0.667216495
"2214",2214,2230,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.545454545,"PS capacity","productivity","phys","dQ",NA,0.454545455,NA,0.262431941,3,100,NA,35.71428571,NA,0.4545,"net PS",1,NA,0.136363636,NA,NA,3,0.8,0.335564161,-0.216731345,0.67058104
"2215",2215,2231,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.363636364,NA,0.209945553,3,100,NA,35.71428571,NA,0.5455,"net PS",1,NA,0.045454545,NA,NA,3,0.8,0.259130779,-0.420987851,0.681435898
"2216",2216,2232,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.818181818,"PS capacity","productivity","phys","dQ",NA,0.204545455,NA,0.118094374,3,190,NA,67.85714286,NA,0.6818,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.193515754,-0.563731408,0.693149425
"2217",2217,2233,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.409090909,"PS capacity","productivity","phys","dQ",NA,0.590909091,NA,0.341161523,3,190,NA,67.85714286,NA,0.5455,"net PS",1,NA,0.318181818,NA,NA,3,0.8,0.474559387,0.229878308,0.671070336
"2218",2218,2234,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.545454545,"PS capacity","productivity","phys","dQ",NA,0.454545455,NA,0.262431941,3,190,NA,67.85714286,NA,0.6364,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.359349734,0.20238577,0.67008
"2219",2219,2235,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.363636364,NA,0.209945553,3,190,NA,67.85714286,NA,0.7727,"net PS",1,NA,0.045454545,NA,NA,3,0.8,0.259130779,0.280658566,0.673230769
"2220",2220,2236,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.090909091,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,10,NA,3.571428571,NA,0.3182,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2221",2221,2237,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.772727273,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,10,NA,3.571428571,NA,0.4545,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2222",2222,2238,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.090909091,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,10,NA,3.571428571,NA,0.4091,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2223",2223,2239,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.818181818,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,10,NA,3.571428571,NA,0.4545,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2224",2224,2240,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.090909091,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,100,NA,35.71428571,NA,0.5,"net PS",1,NA,0.090909091,NA,NA,3,0.8,0.143739894,-3.288768767,1.568
"2225",2225,2241,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.772727273,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,100,NA,35.71428571,NA,0.5455,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.231773614,-0.784464541,0.717948718
"2226",2226,2242,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.090909091,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,100,NA,35.71428571,NA,0.8182,"net PS",1,NA,0.136363636,NA,NA,3,0.8,0.160706087,-1.35764502,0.820266667
"2227",2227,2243,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.818181818,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,100,NA,35.71428571,NA,0.6364,"net PS",1,NA,0.318181818,NA,NA,3,0.8,0.259130778,-0.561317132,0.692923077
"2228",2228,2244,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.090909091,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,190,NA,67.85714286,NA,0.8636,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.181818182,-1,0.75
"2229",2229,2245,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.772727273,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,190,NA,67.85714286,NA,0.8182,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.251030932,0.144857194,0.668415301
"2230",2230,2246,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.090909091,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,190,NA,67.85714286,NA,1.1364,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.181818182,0.2,0.67
"2231",2231,2247,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.818181818,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,190,NA,67.85714286,NA,1.3182,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.205804208,1.943594859,0.981463415
"2232",2232,2248,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.5,"PS capacity","productivity","phys","dQ",NA,0.227272727,NA,0.13121597,3,10,NA,3.571428571,NA,0.3182,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2233",2233,2249,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,10,NA,3.571428571,NA,0.3182,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2234",2234,2250,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,10,NA,3.571428571,NA,0.2727,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2235",2235,2251,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.863636364,"PS capacity","productivity","phys","dQ",NA,0.090909091,NA,0.052486388,3,10,NA,3.571428571,NA,0.3182,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2236",2236,2252,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.5,"PS capacity","productivity","phys","dQ",NA,0.227272727,NA,0.13121597,3,100,NA,35.71428571,NA,0.5455,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.227272727,0.16,0.6688
"2237",2237,2253,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,100,NA,35.71428571,NA,0.5455,"net PS",1,NA,0.272727273,NA,NA,3,0.8,0.231773614,-0.470678724,0.685128205
"2238",2238,2254,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,100,NA,35.71428571,NA,0.4091,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.251030932,-0.869143162,0.729617486
"2239",2239,2255,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.863636364,"PS capacity","productivity","phys","dQ",NA,0.090909091,NA,0.052486388,3,100,NA,35.71428571,NA,0.6818,"net PS",1,NA,0.272727273,NA,NA,3,0.8,0.203278907,-0.715541753,0.709333333
"2240",2240,2256,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.5,"PS capacity","productivity","phys","dQ",NA,0.227272727,NA,0.13121597,3,190,NA,67.85714286,NA,0.6818,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.205804208,0.706761767,0.708292683
"2241",2241,2257,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,190,NA,67.85714286,NA,0.5909,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.181818182,-0.4,0.68
"2242",2242,2258,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.681818182,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,190,NA,67.85714286,NA,0.7273,"net PS",1,NA,0.090909091,NA,NA,3,0.8,0.203278907,0.178885438,0.669333333
"2243",2243,2259,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,3,NA,NA,NA,NA,NA,0,280,NA,100,NA,0.863636364,"PS capacity","productivity","phys","dQ",NA,0.090909091,NA,0.052486388,3,190,NA,67.85714286,NA,0.8636,"net PS",1,NA,0.090909091,NA,NA,3,0.8,0.090909091,0,0.666666667
"2244",2244,2260,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.954545455,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,10,NA,3.571428571,NA,0.1364,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2245",2245,2261,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,2.090909091,"PS capacity","productivity","phys","dQ",NA,0.136363636,NA,0.078729582,3,10,NA,3.571428571,NA,0.1818,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2246",2246,2262,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"10",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,2.045454545,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,10,NA,3.571428571,NA,0.2273,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2247",2247,2263,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,20,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,3,"PS capacity","productivity","phys","dQ",NA,0.136363636,NA,0.078729582,3,10,NA,3.571428571,NA,0.4545,"net PS",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2248",2248,2264,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.954545455,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,100,NA,35.71428571,NA,0.6818,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.251030932,-4.056001423,2.037595628
"2249",2249,2265,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"15",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,2.090909091,"PS capacity","productivity","phys","dQ",NA,0.136363636,NA,0.078729582,3,100,NA,35.71428571,NA,0.6818,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.187413892,-6.014883501,3.681568627
"2250",2250,2266,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,2.045454545,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,100,NA,35.71428571,NA,0.5909,"net PS",1,NA,0.227272727,NA,NA,3,0.8,0.205804208,-5.654094135,3.330731707
"2251",2251,2267,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,3,"PS capacity","productivity","phys","dQ",NA,0.136363636,NA,0.078729582,3,100,NA,35.71428571,NA,1,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.160706087,-9.956063479,8.926933333
"2252",2252,2268,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"20",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,1.954545455,"PS capacity","productivity","phys","dQ",NA,0.272727273,NA,0.157459164,3,190,NA,67.85714286,NA,1.0909,"net PS",1,NA,0.136363636,NA,NA,3,0.8,0.21560984,-3.204441362,1.52237037
"2253",2253,2269,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,2.090909091,"PS capacity","productivity","phys","dQ",NA,0.136363636,NA,0.078729582,3,190,NA,67.85714286,NA,1.2273,"net PS",1,NA,0.181818182,NA,NA,3,0.8,0.160706087,-4.29920923,2.206933333
"2254",2254,2270,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,2.045454545,"PS capacity","productivity","phys","dQ",NA,0.181818182,NA,0.104972776,3,190,NA,67.85714286,NA,1.3182,"net PS",1,NA,0.136363636,NA,NA,3,0.8,0.160706087,-3.62038672,1.758933333
"2255",2255,2271,"993","Sliwinska-Wilczewska, S; Cieszynska, A; Maculewicz, J; Latala, A",2018,"Ecophysiological characteristics of red, green, and brown strains of the Baltic picocyanobacterium Synechococcus sp - a laboratory study","BIOGEOSCIENCES",1,"25",NA,"Fig. S4",NA,NA,"Lab","coastal",NA,NA,"Gulf of Gdansk","Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",0.25,NA,"No","Sal","gradient","16",NA,NA,25,NA,NA,18,NA,NA,NA,NA,NA,0,280,NA,100,NA,3,"PS capacity","productivity","phys","dQ",NA,0.136363636,NA,0.078729582,3,190,NA,67.85714286,NA,1.6818,"net PS",1,NA,0.090909091,NA,NA,3,0.8,0.115886807,-9.09978867,7.567179487
"2256",2256,2272,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",0,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.162790698,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,25,NA,45.45454545,NA,0.1628,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2257",2257,2273,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",1,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.093023256,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,25,NA,45.45454545,NA,0.186,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2258",2258,2274,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",2,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.093023256,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,25,NA,45.45454545,NA,0.1395,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2259",2259,2275,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",3,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.046511628,"Chl a (µg L-1)","biom","biom","SS",NA,0.06976744,NA,0.04028025,3,25,NA,45.45454545,NA,0.1628,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2260",2260,2276,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",4,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.11627907,"Chl a (µg L-1)","biom","biom","SS",NA,0.06976744,NA,0.04028025,3,25,NA,45.45454545,NA,0.2326,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2261",2261,2277,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.209302326,"Chl a (µg L-1)","biom","biom","SS",NA,0.04651163,NA,0.026853502,3,25,NA,45.45454545,NA,0.3256,"Chl a (µg L-1)",2,NA,0.09302326,NA,0.053707004,3,0.8,0.073541344,1.264911007,0.799999988
"2262",2262,2278,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",6,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.279069767,"Chl a (µg L-1)","biom","biom","SS",NA,0.13953488,NA,0.080560501,3,25,NA,45.45454545,NA,0.4651,"Chl a (µg L-1)",2,NA,0.09302326,NA,0.053707004,3,0.8,0.118581849,1.255143271,0.797948719
"2263",2263,2279,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",7,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.441860465,"Chl a (µg L-1)","biom","biom","SS",NA,0.39534884,NA,0.228254759,3,25,NA,45.45454545,NA,0.8605,"Chl a (µg L-1)",2,NA,0.27906977,NA,0.161121007,3,0.8,0.34218463,0.978663831,0.746481908
"2264",2264,2280,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",8,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.488372093,"Chl a (µg L-1)","biom","biom","SS",NA,0.30232558,NA,0.174547755,3,25,NA,45.45454545,NA,0.814,"Chl a (µg L-1)",2,NA,0.25581395,NA,0.147694253,3,0.8,0.280037081,0.930109382,0.738758622
"2265",2265,2281,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",9,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.76744186,"Chl a (µg L-1)","biom","biom","SS",NA,0.51162791,NA,0.295388512,3,25,NA,45.45454545,NA,1.1395,"Chl a (µg L-1)",2,NA,0.20930233,NA,0.120840757,3,0.8,0.390877592,0.761554064,0.714997049
"2266",2266,2282,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",0,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.186046512,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,25,NA,45.45454545,NA,0.186,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2267",2267,2283,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",1,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.162790698,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,25,NA,45.45454545,NA,0.1395,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2268",2268,2284,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",2,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.11627907,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,25,NA,45.45454545,NA,0.1163,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2269",2269,2285,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",3,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.11627907,"Chl a (µg L-1)","biom","biom","SS",NA,0.06976744,NA,NA,3,25,NA,45.45454545,NA,0.1163,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2270",2270,2286,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",4,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.162790698,"Chl a (µg L-1)","biom","biom","SS",NA,0.06976744,NA,NA,3,25,NA,45.45454545,NA,0.1628,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2271",2271,2287,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.279069767,"Chl a (µg L-1)","biom","biom","SS",NA,0.06976744,NA,0.080560501,3,25,NA,45.45454545,NA,0.2093,"Chl a (µg L-1)",2,NA,0.13953488,NA,0.080560501,3,0.8,0.110312008,-0.505964439,0.688000001
"2272",2272,2288,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",6,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.534883721,"Chl a (µg L-1)","biom","biom","SS",NA,0.13953488,NA,0.080560501,3,25,NA,45.45454545,NA,0.3488,"Chl a (µg L-1)",2,NA,0.13953488,NA,0.080560501,3,0.8,0.13953488,-1.066666695,0.761481487
"2273",2273,2289,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",7,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,0.813953488,"Chl a (µg L-1)","biom","biom","SS",NA,0.23255814,NA,0.255108261,3,25,NA,45.45454545,NA,0.6977,"Chl a (µg L-1)",2,NA,0.44186047,NA,0.255108261,3,0.8,0.353075037,-0.263465966,0.672451193
"2274",2274,2290,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",8,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,1.511627907,"Chl a (µg L-1)","biom","biom","SS",NA,0.6744186,NA,0.30881526,3,25,NA,45.45454545,NA,0.8372,"Chl a (µg L-1)",2,NA,0.53488372,NA,0.30881526,3,0.8,0.608662896,-0.886426439,0.732145986
"2275",2275,2291,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",9,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.69,9.13,NA,NA,7.18,2,55,NA,100,NA,2.534883721,"Chl a (µg L-1)","biom","biom","SS",NA,0.11627907,NA,0.375949012,3,25,NA,45.45454545,NA,1.5814,"Chl a (µg L-1)",2,NA,0.65116279,NA,0.375949012,3,0.8,0.46772524,-1.630852115,0.888306552
"2276",2276,2292,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",0,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.504219823,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,18,NA,22.5,NA,0.5042,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2277",2277,2293,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",1,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.536604514,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,18,NA,22.5,NA,0.4609,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2278",2278,2294,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",2,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.341118744,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,18,NA,22.5,NA,0.4171,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2279",2279,2295,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",3,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.488027478,"Chl a (µg L-1)","biom","biom","SS",NA,0.151619235,NA,0.087537406,3,18,NA,22.5,NA,0.5257,"Chl a (µg L-1)",2,NA,0.113935231,NA,0.065780536,3,0.8,0.134107474,0.22479883,0.670877876
"2280",2280,2296,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",4,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.368498528,"Chl a (µg L-1)","biom","biom","SS",NA,0.113935231,NA,0.065780536,3,18,NA,22.5,NA,0.5584,"Chl a (µg L-1)",2,NA,0.07595682,NA,0.043853691,3,0.8,0.096826327,1.568929081,0.871794872
"2281",2281,2297,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.553091266,"Chl a (µg L-1)","biom","biom","SS",NA,0.113935231,NA,0.065780536,3,18,NA,22.5,NA,0.5528,"Chl a (µg L-1)",2,NA,0.113935231,NA,0.065780536,3,0.8,0.113935231,-0.002067183,0.666667023
"2282",2282,2298,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",6,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.623454367,"Chl a (µg L-1)","biom","biom","SS",NA,0.114524043,NA,0.066120487,3,18,NA,22.5,NA,0.6614,"Chl a (µg L-1)",2,NA,0.113935231,NA,0.065780536,3,0.8,0.114230016,0.265978498,0.672562047
"2283",2283,2299,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",7,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.922276742,"Chl a (µg L-1)","biom","biom","SS",NA,0.113346418,NA,0.065440585,3,18,NA,22.5,NA,0.6938,"Chl a (µg L-1)",2,NA,0.07595682,NA,0.043853691,3,0.8,0.096480177,-1.894352032,0.965714135
"2284",2284,2300,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",0,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.503631011,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,18,NA,22.5,NA,0.4662,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2285",2285,2301,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",1,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.384396467,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,18,NA,22.5,NA,0.5369,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2286",2286,2302,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",2,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.34141315,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,18,NA,22.5,NA,0.531,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2287",2287,2303,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",3,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.412070658,"Chl a (µg L-1)","biom","biom","SS",NA,0.114229637,NA,0.065950512,3,18,NA,22.5,NA,0.5257,"Chl a (µg L-1)",2,NA,0.151913641,NA,0.087707381,3,0.8,0.134398966,0.676438681,0.704797441
"2288",2288,2304,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",4,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,0.71030422,"Chl a (µg L-1)","biom","biom","SS",NA,0.151913641,NA,0.087707381,3,18,NA,22.5,NA,0.7483,"Chl a (µg L-1)",2,NA,0.151913641,NA,0.087707381,3,0.8,0.151913641,0.2,0.67
"2289",2289,2305,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,1.160451423,"Chl a (µg L-1)","biom","biom","SS",NA,0.113935231,NA,0.065780536,3,18,NA,22.5,NA,0.8186,"Chl a (µg L-1)",2,NA,0.114229637,NA,0.065950512,3,0.8,0.114082529,-2.39690123,1.145427959
"2290",2290,2306,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",6,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,2.446418057,"Chl a (µg L-1)","biom","biom","SS",NA,0.379784102,NA,0.219268454,3,18,NA,22.5,NA,1.0412,"Chl a (µg L-1)",2,NA,0.113935231,NA,0.065780536,3,0.8,0.280372253,-4.009529932,2.006360856
"2291",2291,2307,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",7,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,80,NA,100,NA,3.884298332,"Chl a (µg L-1)","biom","biom","SS",NA,0.721589794,NA,0.416610062,3,18,NA,22.5,NA,1.7955,"Chl a (µg L-1)",2,NA,0.113640824,NA,0.065610561,3,0.8,0.5165298,-3.235147421,1.538848237
"2292",2292,2308,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,0.989706443,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,20,NA,44.44444444,NA,1.1209,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2293",2293,2309,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.017155928,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,20,NA,44.44444444,NA,1.1483,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2294",2294,2310,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.306900496,"Chl a (µg L-1)","biom","biom","SS",NA,0.39140933,NA,0.225980282,3,20,NA,44.44444444,NA,1.3049,"Chl a (µg L-1)",2,NA,0.39344262,NA,0.227154203,3,0.8,0.392427292,-0.004145064,0.666668098
"2295",2295,2311,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.592578472,"Chl a (µg L-1)","biom","biom","SS",NA,0.39547592,NA,0.228328129,3,20,NA,44.44444444,NA,1.5936,"Chl a (µg L-1)",2,NA,0.39344262,NA,0.227154203,3,0.8,0.39446058,0.002061849,0.666667021
"2296",2296,2312,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.753208794,"Chl a (µg L-1)","biom","biom","SS",NA,0.39140933,NA,0.225980282,3,20,NA,44.44444444,NA,1.8813,"Chl a (µg L-1)",2,NA,0.39445927,NA,0.227741166,3,0.8,0.392937259,0.260800105,0.672334725
"2297",2297,2313,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.90773923,"Chl a (µg L-1)","biom","biom","SS",NA,0.39344262,NA,0.227154203,3,20,NA,44.44444444,NA,2.5635,"Chl a (µg L-1)",2,NA,0.39344262,NA,0.227154203,3,0.8,0.39344262,1.333333343,0.814814817
"2298",2298,2314,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,0.990723091,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,20,NA,44.44444444,NA,1.1209,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2299",2299,2315,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.147286822,"Chl a (µg L-1)","biom","biom","SS",NA,NA,NA,NA,3,20,NA,44.44444444,NA,1.2795,"Chl a (µg L-1)",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2300",2300,2316,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,1.697293176,"Chl a (µg L-1)","biom","biom","SS",NA,0.26229508,NA,0.151436135,3,20,NA,44.44444444,NA,1.8295,"Chl a (µg L-1)",2,NA,0.39344262,NA,0.227154203,3,0.8,0.334361933,0.316218267,0.674999499
"2301",2301,2317,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,3.691955776,"Chl a (µg L-1)","biom","biom","SS",NA,0.26229508,NA,0.151436135,3,20,NA,44.44444444,NA,2.9051,"Chl a (µg L-1)",2,NA,0.39344262,NA,0.227154203,3,0.8,0.334361933,-1.882714911,0.962051286
"2302",2302,2318,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,4.6364214,"Chl a (µg L-1)","biom","biom","SS",NA,0.6557377,NA,0.378590338,3,20,NA,44.44444444,NA,4.7686,"Chl a (µg L-1)",2,NA,0.7858686,NA,0.453721448,3,0.8,0.723733856,0.146091481,0.668445227
"2303",2303,2319,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. S3","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,13.3175753,"Chl a (µg L-1)","biom","biom","SS",NA,2.23052484,NA,1.287794117,3,20,NA,44.44444444,NA,9.1198,"Chl a (µg L-1)",2,NA,0.52560681,NA,0.303459233,3,0.8,1.620417166,-2.072423348,1.024578211
"2304",2304,2320,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",20,NA,16,NA,NA,NA,0.41,2.95,NA,NA,3.71,2,45,NA,100,NA,0.339130435,"Fv/Fm","productivity","phys","dQ",NA,0.056521739,NA,0.032632841,3,20,NA,44.44444444,NA,0.2739,"Fv/Fm",1,NA,0.013043478,NA,0.007530656,3,0.8,0.041017309,-1.271997456,0.801498127
"2305",2305,2321,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","Si","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,0.339130435,"Fv/Fm","productivity","phys","dQ",NA,0.056521739,NA,0.032632841,3,20,NA,44.44444444,NA,0.313,"Fv/Fm",1,NA,0.030434783,NA,0.01757153,3,0.8,0.045392637,-0.459756617,0.684281346
"2306",2306,2322,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,0.339130435,"Fv/Fm","productivity","phys","dQ",NA,0.056521739,NA,0.032632841,3,20,NA,44.44444444,NA,0.4304,"Fv/Fm",1,NA,0.008695652,NA,0.005020437,3,0.8,0.04043712,1.806347191,0.938574181
"2307",2307,2323,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,120,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",20,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,45,NA,100,NA,0.339130435,"Fv/Fm","productivity","phys","dQ",NA,0.056521739,NA,0.032632841,3,20,NA,44.44444444,NA,0.413,"Fv/Fm",1,NA,0.013043478,NA,0.007530656,3,0.8,0.041017309,1.441597117,0.839850187
"2308",2308,2324,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",18,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,80,NA,100,NA,0.134782609,"Fv/Fm","productivity","phys","dQ",NA,0.013043478,NA,0.007530656,3,18,NA,22.5,NA,0.2478,"Fv/Fm",1,NA,0.017391304,NA,0.010040874,3,0.8,0.015371887,5.883128419,3.550933333
"2309",2309,2325,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,80,NA,100,NA,0.134782609,"Fv/Fm","productivity","phys","dQ",NA,0.013043478,NA,0.007530656,3,18,NA,22.5,NA,0.4217,"Fv/Fm",1,NA,0.017391304,NA,0.010040874,3,0.8,0.015371887,14.93409522,19.25226667
"2310",2310,2326,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,80,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",18,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,80,NA,100,NA,0.134782609,"Fv/Fm","productivity","phys","dQ",NA,0.013043478,NA,0.007530656,3,18,NA,22.5,NA,0.4261,"Fv/Fm",1,NA,0.017391304,NA,0.010040874,3,0.8,0.015371887,15.16036939,19.81973333
"2311",2311,2327,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","none","light reduced","12",25,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,55,NA,100,NA,0.2,"Fv/Fm","productivity","phys","dQ",NA,0.008695652,NA,0.005020437,3,25,NA,45.45454545,NA,0.2174,"Fv/Fm",1,NA,0.02173913,NA,0.012551093,3,0.8,0.016556028,0.84036117,0.725517241
"2312",2312,2328,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,55,NA,100,NA,0.2,"Fv/Fm","productivity","phys","dQ",NA,0.008695652,NA,0.005020437,3,25,NA,45.45454545,NA,0.4217,"Fv/Fm",1,NA,0.02173913,NA,0.012551093,3,0.8,0.016556028,10.71460492,10.23356322
"2313",2313,2329,"999","Hogle, Shane L.; Dupont, Christopher L.; Hopkinson, Brian M.; King, Andrew L.; Buck, Kristen N.; Roe, Kelly L.; Stuart, Rhona K.; Allen, Andrew E.; Mann, Elizabeth L.; Johnson, Zackary I.; Barbeau, Katherine A.",2018,"Pervasive iron limitation at subsurface chlorophyll maxima of the California Current","PNAS",1,"elevated light treatment is control here",NA,"Fig. 2","summer","2007","Field","seawater",NA,40,"ocean","total phytoplankton","phytoplankton",5,"microcosm","culture flask",4,NA,"No","FE","light reduced","12",25,NA,16,NA,NA,NA,0.31,3.46,NA,NA,3.83,2,55,NA,100,NA,0.2,"Fv/Fm","productivity","phys","dQ",NA,0.008695652,NA,0.005020437,3,25,NA,45.45454545,NA,0.3652,"Fv/Fm",1,NA,0.017391304,NA,0.010040874,3,0.8,0.013749033,9.613324087,8.368
"2314",2314,2330,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",0.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,45.94871795,"fluorescence","biomass","biom","SS",NA,10.05128205,NA,5.803110398,3,NA,NA,NA,1000,-5.7436,"fluorescence",2,NA,5.743589744,NA,3.316063085,3,0.8,8.185874847,-5.051854191,2.793435897
"2315",2315,2331,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",1,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,1.435897436,"fluorescence","biomass","biom","SS",NA,5.743589744,NA,3.316063085,3,NA,NA,NA,1000,17.2308,"fluorescence",2,NA,22.97435897,NA,13.26425234,3,0.8,16.74529775,0.754593775,0.714117647
"2316",2316,2332,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",1.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,40.20512821,"fluorescence","biomass","biom","SS",NA,57.43589744,NA,33.16063085,3,NA,NA,NA,1000,64.6154,"fluorescence",2,NA,10.05128205,NA,5.803110398,3,0.8,41.2305141,0.473634772,0.685360825
"2317",2317,2333,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",2,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,17.23076923,"fluorescence","biomass","biom","SS",NA,5.743589744,NA,3.316063085,3,NA,NA,NA,1000,132.1026,"fluorescence",2,NA,81.84615385,NA,47.25389896,3,0.8,58.01629824,1.583993441,0.875752935
"2318",2318,2334,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",2.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,33.02564103,"fluorescence","biomass","biom","SS",NA,18.66666667,NA,10.77720502,3,NA,NA,NA,1000,130.6667,"fluorescence",2,NA,38.76923077,NA,22.38342582,3,0.8,30.42612117,2.567294729,1.215916852
"2319",2319,2335,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",3,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,35.8974359,"fluorescence","biomass","biom","SS",NA,63.17948718,NA,36.47669393,3,NA,NA,NA,1000,162.2564,"fluorescence",2,NA,60.30769231,NA,34.81866239,3,0.8,61.76028397,1.636766754,0.889917117
"2320",2320,2336,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",3.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,100.5128205,"fluorescence","biomass","biom","SS",NA,53.12820513,NA,30.67358353,3,NA,NA,NA,1000,229.7436,"fluorescence",2,NA,33.02564103,NA,19.06736274,3,0.8,44.23403184,2.337218903,1.121882684
"2321",2321,2337,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",0.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,1.137614679,"cell/ ml","abundance","biom","SS",NA,0.220183486,NA,0.127122995,3,NA,NA,NA,1000,1.211,"cell/ ml",2,NA,0.550458716,NA,0.317807488,3,0.8,0.419216868,0.140060195,0.668301405
"2322",2322,2338,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",1,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,1.908256881,"cell/ ml","abundance","biom","SS",NA,0.220183486,NA,0.127122995,3,NA,NA,NA,1000,1.4679,"cell/ ml",2,NA,0.146788991,NA,0.084748663,3,0.8,0.187119982,-1.882714897,0.962051282
"2323",2323,2339,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",1.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,2.605504587,"cell/ ml","abundance","biom","SS",NA,0.403669725,NA,0.233058824,3,NA,NA,NA,1000,1.2844,"cell/ ml",2,NA,0.440366972,NA,0.25424599,3,0.8,0.422417043,-2.501984118,1.188327044
"2324",2324,2340,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",2,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,3.706422018,"cell/ ml","abundance","biom","SS",NA,0.366972477,NA,0.211871658,3,NA,NA,NA,1000,2.3853,"cell/ ml",2,NA,0.403669725,NA,0.233058824,3,0.8,0.385757726,-2.739752606,1.292187029
"2325",2325,2341,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",2.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,3.082568807,"cell/ ml","abundance","biom","SS",NA,1.247706422,NA,0.720363639,3,NA,NA,NA,1000,2.6055,"cell/ ml",2,NA,0.293577982,NA,0.169497327,3,0.8,0.906355159,-0.421083692,0.681442623
"2326",2326,2342,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",3,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,3.633027523,"cell/ ml","abundance","biom","SS",NA,1.137614679,NA,0.656802141,3,NA,NA,NA,1000,2.5321,"cell/ ml",2,NA,0.293577982,NA,0.169497327,3,0.8,0.830769279,-1.06014265,0.760325203
"2327",2327,2343,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Pseudonana fluorescens","microalgae",3.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,4.80733945,"cell/ ml","abundance","biom","SS",NA,0.110091743,NA,0.063561498,3,NA,NA,NA,1000,3.3761,"cell/ ml",2,NA,0.293577982,NA,0.169497327,3,0.8,0.221707266,-5.164260745,2.88913242
"2328",2328,2344,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",0.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,7929.816566,"cell/ ml","abundance","biom","SS",NA,4375.071209,NA,2525.94854,3,NA,NA,NA,1000,3597.2808,"cell/ ml",2,NA,2187.535604,NA,1262.97427,3,0.8,3458.797486,-1.002090654,0.750348807
"2329",2329,2345,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",1,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,8856.480954,"cell/ ml","abundance","biom","SS",NA,2386.54058,NA,1377.869846,3,NA,NA,NA,1000,4128.9735,"cell/ ml",2,NA,1194.029851,NA,689.3734557,3,0.8,1886.966245,-2.004278566,1.001427714
"2330",2330,2346,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",1.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,5207.550036,"cell/ ml","abundance","biom","SS",NA,796.0199005,NA,459.5823038,3,NA,NA,NA,1000,3067.1072,"cell/ ml",2,NA,797.5390224,NA,460.4593693,3,0.8,796.7798235,-2.149093399,1.051550203
"2331",2331,2347,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",2,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,8921.803198,"cell/ ml","abundance","biom","SS",NA,996.5439976,NA,575.3549453,3,NA,NA,NA,1000,3200.7899,"cell/ ml",2,NA,796.0199005,NA,459.5823038,3,0.8,901.8723915,-5.07478735,2.812788887
"2332",2332,2348,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",2.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,3878.318332,"cell/ ml","abundance","biom","SS",NA,1393.034826,NA,804.2690317,3,NA,NA,NA,1000,3130.9103,"cell/ ml",2,NA,1792.563898,NA,1034.937249,3,0.8,1605.277446,-0.372475425,0.678228162
"2333",2333,2349,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",3,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,21326.95302,"cell/ ml","abundance","biom","SS",NA,4376.590331,NA,2526.825606,3,NA,NA,NA,1000,1873.0774,"cell/ ml",2,NA,597.0149254,NA,344.6867279,3,0.8,3123.377158,-4.982779773,2.735674522
"2334",2334,2350,"1001","Camara, AD; Fernandes, LDD",2018,"Evaluation of the interactions between the marine bacterium Pseudomonas fluorescens and the microalga Isochrysis galbana in simulated ballast tank environment","Archives of Microbiology",1,NA,NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Isochrysis galbana","microalgae",3.5,"microcosm","culture flask",0.25,NA,"No","none","shading","12",NA,NA,25,7,NA,NA,NA,NA,NA,NA,NA,0,NA,NA,100,1000,27031.25593,"cell/ ml","abundance","biom","SS",NA,14724.84904,NA,8501.395555,3,NA,NA,NA,1000,1605.7119,"cell/ ml",2,NA,595.4958034,NA,343.8096624,3,0.8,10420.55167,-1.95195378,0.984176963
"2335",2335,2351,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,86451.6129,"cell/ l","abundance","biom","SS",NA,19354.83871,NA,11174.52134,3,90,NA,75,NA,61290.3226,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2336",2336,2352,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,196774.1935,"cell/ l","abundance","biom","SS",NA,63870.96774,NA,36875.92042,3,90,NA,75,NA,80645.1613,"cell/ l",2,NA,52258.0645,NA,30171.20761,3,0.8,58354.1165,-1.592059505,0.877887789
"2337",2337,2353,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,183225.8065,"cell/ l","abundance","biom","SS",NA,79354.83871,NA,45815.53749,3,90,NA,75,NA,150322.5806,"cell/ l",2,NA,79354.8387,NA,45815.53748,3,0.8,79354.8387,-0.331707317,0.675835812
"2338",2338,2354,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,45806.45161,"cell/ l","abundance","biom","SS",NA,7741.935484,NA,4469.808536,3,90,NA,75,NA,90322.5806,"cell/ l",2,NA,32903.2258,NA,18996.68627,3,0.8,23901.46264,1.489988448,0.851672131
"2339",2339,2355,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.975,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,30322.58065,"cell/ l","abundance","biom","SS",NA,9677.419355,NA,5587.26067,3,90,NA,75,NA,223870.9677,"cell/ l",2,NA,73548.3871,NA,42463.18109,3,0.8,52454.82671,2.951848655,1.392784207
"2340",2340,2356,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,20000,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,6666.6667,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2341",2341,2357,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,86451.6129,"cell/ l","abundance","biom","SS",NA,19354.83871,NA,11174.52134,3,90,NA,75,NA,61290.3226,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2342",2342,2358,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,196774.1935,"cell/ l","abundance","biom","SS",NA,63870.96774,NA,36875.92042,3,90,NA,75,NA,80645.1613,"cell/ l",2,NA,52258.0645,NA,30171.20761,3,0.8,58354.1165,-1.592059505,0.877887789
"2343",2343,2359,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,183225.8065,"cell/ l","abundance","biom","SS",NA,79354.83871,NA,45815.53749,3,90,NA,75,NA,150322.5806,"cell/ l",2,NA,79354.8387,NA,45815.53748,3,0.8,79354.8387,-0.331707317,0.675835812
"2344",2344,2360,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,45806.45161,"cell/ l","abundance","biom","SS",NA,7741.935484,NA,4469.808536,3,90,NA,75,NA,90322.5806,"cell/ l",2,NA,32903.2258,NA,18996.68627,3,0.8,23901.46264,1.489988448,0.851672131
"2345",2345,2361,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.975,NA,34.41,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,30322.58065,"cell/ l","abundance","biom","SS",NA,9677.419355,NA,5587.26067,3,90,NA,75,NA,223870.9677,"cell/ l",2,NA,73548.3871,NA,42463.18109,3,0.8,52454.82671,2.951848655,1.392784207
"2346",2346,2362,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.3","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",22,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,20000,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,6666.6667,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2347",2347,2363,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,86451.6129,"cell/ l","abundance","biom","SS",NA,19354.83871,NA,11174.52134,3,90,NA,75,NA,61290.3226,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2348",2348,2364,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,196774.1935,"cell/ l","abundance","biom","SS",NA,63870.96774,NA,36875.92042,3,90,NA,75,NA,80645.1613,"cell/ l",2,NA,52258.0645,NA,30171.20761,3,0.8,58354.1165,-1.592059505,0.877887789
"2349",2349,2365,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,183225.8065,"cell/ l","abundance","biom","SS",NA,79354.83871,NA,45815.53749,3,90,NA,75,NA,150322.5806,"cell/ l",2,NA,79354.8387,NA,45815.53748,3,0.8,79354.8387,-0.331707317,0.675835812
"2350",2350,2366,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,45806.45161,"cell/ l","abundance","biom","SS",NA,7741.935484,NA,4469.808536,3,90,NA,75,NA,90322.5806,"cell/ l",2,NA,32903.2258,NA,18996.68627,3,0.8,23901.46264,1.489988448,0.851672131
"2351",2351,2367,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.975,NA,34.41,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,30322.58065,"cell/ l","abundance","biom","SS",NA,9677.419355,NA,5587.26067,3,90,NA,75,NA,223870.9677,"cell/ l",2,NA,73548.3871,NA,42463.18109,3,0.8,52454.82671,2.951848655,1.392784207
"2352",2352,2368,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",0,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,20000,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,6666.6667,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2353",2353,2369,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,73333.33333,"cell/ l","abundance","biom","SS",NA,133333.333,NA,76980.0357,3,90,NA,75,NA,86666.6667,"cell/ l",2,NA,80000,NA,46188.02154,3,0.8,109949.4831,0.09701425,0.66745098
"2354",2354,2370,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,166666.6667,"cell/ l","abundance","biom","SS",NA,2e+05,NA,115470.0538,3,90,NA,75,NA,1500000,"cell/ l",2,NA,746666.667,NA,431088.2012,3,0.8,546585.36,1.951509763,0.98403253
"2355",2355,2371,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig.4","winter","2015","Lab","culture",NA,NA,NA,"diatom","phytoplankton",19,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,86666.66667,"cell/ l","abundance","biom","SS",NA,106666.667,NA,61584.02891,3,90,NA,75,NA,566666.6667,"cell/ l",2,NA,246666.667,NA,142413.0666,3,0.8,190029.2378,2.020741673,1.006949742
"2356",2356,2372,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,12972.97297,"cell/ l","abundance","biom","SS",NA,5405.405405,NA,3120.812266,3,90,NA,75,NA,15675.6757,"cell/ l",2,NA,2702.702703,NA,1560.406133,3,0.8,4273.348189,0.505964426,0.688
"2357",2357,2373,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig.5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,11891.89189,"cell/ l","abundance","biom","SS",NA,3243.243243,NA,1872.48736,3,90,NA,75,NA,10810.8108,"cell/ l",2,NA,4324.324324,NA,2496.649813,3,0.8,3822.198817,-0.22627417,0.670933333
"2358",2358,2374,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,14594.59459,"cell/ l","abundance","biom","SS",NA,4324.324324,NA,2496.649813,3,90,NA,75,NA,23243.2432,"cell/ l",2,NA,9189.189189,NA,5305.380852,3,0.8,7181.259598,0.96346871,0.744022663
"2359",2359,2375,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,22162.16216,"cell/ l","abundance","biom","SS",NA,3783.783784,NA,2184.568586,3,90,NA,75,NA,18378.3784,"cell/ l",2,NA,11891.89189,NA,6865.786985,3,0.8,8824.231199,-0.343035779,0.676472795
"2360",2360,2376,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.975,NA,34.41,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,78378.37838,"cell/ l","abundance","biom","SS",NA,8648.648649,NA,4993.299625,3,90,NA,75,NA,22162.1622,"cell/ l",2,NA,5945.945946,NA,3432.893492,3,0.8,7421.367685,-6.059930579,3.726896552
"2361",2361,2377,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",0,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,6302.021403,"cell/ l","abundance","biom","SS",NA,6678.557273,NA,3855.866839,3,90,NA,75,NA,4604.307,"cell/ l",2,NA,10067.3801,NA,5812.404613,3,0.8,8542.694815,-0.158986306,0.668773054
"2362",2362,2378,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,7378.781873,"cell/ l","abundance","biom","SS",NA,11745.27679,NA,6781.138715,3,90,NA,75,NA,64427.2691,"cell/ l",2,NA,97318.00766,NA,56186.57792,3,0.8,69313.58504,0.65843932,0.702795195
"2363",2363,2379,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,13660.9856,"cell/ l","abundance","biom","SS",NA,8389.483419,NA,4843.67051,3,90,NA,75,NA,22063.6808,"cell/ l",2,NA,20128.15431,NA,11620.99531,3,0.8,15419.56595,0.435949766,0.68250435
"2364",2364,2380,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 5","winter","2015","Lab","culture",NA,NA,NA,"dinoflagellate","phytoplankton",19,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,16428.85454,"cell/ l","abundance","biom","SS",NA,25181.66204,NA,14538.63936,3,90,NA,75,NA,18126.5689,"cell/ l",2,NA,21792.83921,NA,12582.10159,3,0.8,23548.29022,0.057676013,0.666943877
"2365",2365,2381,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,953271.028,"cell/ l","abundance","biom","SS",NA,448598.1308,NA,258998.2516,3,90,NA,75,NA,579439.2523,"cell/ l",2,NA,373831.7757,NA,215831.8763,3,0.8,412910.6922,-0.724285968,0.710382514
"2366",2366,2382,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,-1,120,NA,100,NA,579439.2523,"cell/ l","abundance","biom","SS",NA,299065.4206,NA,172665.5011,3,90,NA,75,NA,1177570.0935,"cell/ l",2,NA,373831.7757,NA,215831.8763,3,0.8,338519.0706,1.413523534,0.833170732
"2367",2367,2383,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1551401.869,"cell/ l","abundance","biom","SS",NA,672897.1963,NA,388497.3774,3,90,NA,75,NA,1476635.514,"cell/ l",2,NA,672897.1963,NA,388497.3774,3,0.8,672897.1963,-0.088888889,0.667325103
"2368",2368,2384,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1102803.738,"cell/ l","abundance","biom","SS",NA,971962.6168,NA,561162.8785,3,90,NA,75,NA,2074766.3551,"cell/ l",2,NA,672897.1963,NA,388497.3774,3,0.8,835913.2626,0.930204279,0.738773333
"2369",2369,2385,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1177570.093,"cell/ l","abundance","biom","SS",NA,672897.1963,NA,388497.3774,3,90,NA,75,NA,1327102.8037,"cell/ l",2,NA,672897.1963,NA,388497.3774,3,0.8,672897.1963,0.177777778,0.669300412
"2370",2370,2386,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,803738.3178,"cell/ l","abundance","biom","SS",NA,149532.7103,NA,86332.75053,3,90,NA,75,NA,429906.5421,"cell/ l",2,NA,299065.4206,NA,172665.5011,3,0.8,236431.9746,-1.264911064,0.8
"2371",2371,2387,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,355140.1869,"cell/ l","abundance","biom","SS",NA,299065.4206,NA,172665.5011,3,90,NA,75,NA,728971.9626,"cell/ l",2,NA,448598.1308,NA,258998.2516,3,0.8,381235.1038,0.784464541,0.717948718
"2372",2372,2388,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,2971962.617,"cell/ l","abundance","biom","SS",NA,299065.4206,NA,172665.5011,3,90,NA,75,NA,1850467.2897,"cell/ l",2,NA,448598.1308,NA,258998.2516,3,0.8,381235.1038,-2.353393622,1.128205128
"2373",2373,2389,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,953271.028,"cell/ l","abundance","biom","SS",NA,373831.7757,NA,215831.8763,3,90,NA,75,NA,1551401.8692,"cell/ l",2,NA,448598.1308,NA,258998.2516,3,0.8,412910.6922,1.158857549,0.778579235
"2374",2374,2390,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,2523364.486,"cell/ l","abundance","biom","SS",NA,299065.4206,NA,172665.5011,3,90,NA,75,NA,1700934.5794,"cell/ l",2,NA,523364.486,NA,302164.6269,3,0.8,426233.8038,-1.543622114,0.865230769
"2375",2375,2391,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,1925233.645,"cell/ l","abundance","biom","SS",NA,747663.5514,NA,431663.7527,3,90,NA,75,NA,1102803.7383,"cell/ l",2,NA,747663.5514,NA,431663.7527,3,0.8,747663.5514,-0.88,0.7312
"2376",2376,2392,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,878504.6729,"cell/ l","abundance","biom","SS",NA,523364.486,NA,302164.6269,3,90,NA,75,NA,953271.028,"cell/ l",2,NA,672897.1963,NA,388497.3774,3,0.8,602785.626,0.099227788,0.667487179
"2377",2377,2393,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,1582089.552,"cell/ l","abundance","biom","SS",NA,194029.8507,NA,112023.1866,3,90,NA,75,NA,567164.1791,"cell/ l",2,NA,119402.9851,NA,68937.34557,3,0.8,161097.2623,-5.040062674,2.783519313
"2378",2378,2394,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,522388.0597,"cell/ l","abundance","biom","SS",NA,74626.86567,NA,43085.84098,3,90,NA,75,NA,925373.1343,"cell/ l",2,NA,208955.2239,NA,120640.3548,3,0.8,156894.0003,2.054814455,1.01852187
"2379",2379,2395,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,402985.0746,"cell/ l","abundance","biom","SS",NA,134328.3582,NA,77554.51377,3,90,NA,75,NA,820895.5224,"cell/ l",2,NA,268656.7164,NA,155109.0275,3,0.8,212391.7831,1.574111546,0.873152263
"2380",2380,2396,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,328358.209,"cell/ l","abundance","biom","SS",NA,164179.1045,NA,94788.85017,3,90,NA,75,NA,641791.0448,"cell/ l",2,NA,194029.8507,NA,112023.1866,3,0.8,179725.2922,1.395164062,0.828873563
"2381",2381,2397,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,89552.23881,"cell/ l","abundance","biom","SS",NA,59701.49254,NA,34468.67279,3,90,NA,75,NA,164179.1045,"cell/ l",2,NA,104477.6119,NA,60320.17738,3,0.8,85087.71829,0.701646415,0.707692308
"2382",2382,2398,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,44776.1194,"cell/ l","abundance","biom","SS",NA,59701.49254,NA,34468.67279,3,90,NA,75,NA,119402.9851,"cell/ l",2,NA,74626.86567,NA,43085.84098,3,0.8,67577.50103,0.883452209,0.731707317
"2383",2383,2399,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,44776.1194,"cell/ l","abundance","biom","SS",NA,74626.86567,NA,43085.84098,3,90,NA,75,NA,134328.3582,"cell/ l",2,NA,59701.49254,NA,34468.67279,3,0.8,67577.50103,1.06014265,0.760325203
"2384",2384,2400,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,44776.1194,"cell/ l","abundance","biom","SS",NA,44776.1194,NA,25851.50459,3,90,NA,75,NA,89552.2388,"cell/ l",2,NA,74626.86567,NA,43085.84098,3,0.8,61538.88993,0.5820855,0.694901961
"2385",2385,2401,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,59701.49254,"cell/ l","abundance","biom","SS",NA,59701.49254,NA,34468.67279,3,90,NA,75,NA,208955.2239,"cell/ l",2,NA,104477.6119,NA,60320.17738,3,0.8,85087.71829,1.403292831,0.830769231
"2386",2386,2402,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,29850.74627,"cell/ l","abundance","biom","SS",NA,44776.1194,NA,25851.50459,3,90,NA,75,NA,134328.3582,"cell/ l",2,NA,29850.74627,NA,17234.33639,3,0.8,38052.38443,2.196500714,1.068717949
"2387",2387,2403,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",15,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,119402.9851,"cell/ l","abundance","biom","SS",NA,179104.4776,NA,103406.0184,3,90,NA,75,NA,119402.9851,"cell/ l",2,NA,74626.86567,NA,43085.84098,3,0.8,137199.8232,0,0.666666667
"2388",2388,2404,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"Synechococcus sp.","phytoplankton",22,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,59701.49254,"cell/ l","abundance","biom","SS",NA,44776.1194,NA,25851.50459,3,90,NA,75,NA,134328.3582,"cell/ l",2,NA,59701.49254,NA,34468.67279,3,0.8,52769.16278,1.13137085,0.773333333
"2389",2389,2405,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,734693.8776,"cell/ l","abundance","biom","SS",NA,244897.9592,NA,141391.9027,3,90,NA,75,NA,367346.9388,"cell/ l",2,NA,244897.9592,NA,141391.9027,3,0.8,244897.9592,-1.2,0.786666667
"2390",2390,2406,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,428571.4286,"cell/ l","abundance","biom","SS",NA,244897.9592,NA,141391.9027,3,90,NA,75,NA,612244.898,"cell/ l",2,NA,183673.4694,NA,106043.927,3,0.8,216461.2595,0.67882251,0.705066667
"2391",2391,2407,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1775510.204,"cell/ l","abundance","biom","SS",NA,2081632.653,NA,1201831.173,3,90,NA,75,NA,1040816.3265,"cell/ l",2,NA,244897.9592,NA,141391.9027,3,0.8,1482087.972,-0.396572345,0.679772469
"2392",2392,2408,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,857142.8571,"cell/ l","abundance","biom","SS",NA,1591836.735,NA,919047.3673,3,90,NA,75,NA,1775510.2041,"cell/ l",2,NA,612244.898,NA,353479.7566,3,0.8,1205982.588,0.609207699,0.697594502
"2393",2393,2409,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,2387755.102,"cell/ l","abundance","biom","SS",NA,2510204.082,NA,1449267.002,3,90,NA,75,NA,918367.3469,"cell/ l",2,NA,612244.898,NA,353479.7566,3,0.8,1827015.099,-0.643404756,0.70116414
"2394",2394,2410,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,367346.9388,"cell/ l","abundance","biom","SS",NA,244897.9592,NA,141391.9027,3,90,NA,75,NA,183673.4694,"cell/ l",2,NA,428571.4286,NA,247435.8297,3,0.8,349033.2934,-0.420987849,0.681435897
"2395",2395,2411,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,122448.9796,"cell/ l","abundance","biom","SS",NA,244897.9592,NA,141391.9027,3,90,NA,75,NA,367346.9388,"cell/ l",2,NA,244897.9592,NA,141391.9027,3,0.8,244897.9592,0.8,0.72
"2396",2396,2412,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,2510204.082,"cell/ l","abundance","biom","SS",NA,1836734.694,NA,1060439.27,3,90,NA,75,NA,857142.8571,"cell/ l",2,NA,244897.9592,NA,141391.9027,3,0.8,1310261.3,-1.009301717,0.751557496
"2397",2397,2413,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,489795.9184,"cell/ l","abundance","biom","SS",NA,122448.9796,NA,70695.95133,3,90,NA,75,NA,612244.898,"cell/ l",2,NA,122448.9796,NA,70695.95133,3,0.8,122448.9796,0.8,0.72
"2398",2398,2414,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1102040.816,"cell/ l","abundance","biom","SS",NA,244897.9592,NA,141391.9027,3,90,NA,75,NA,857142.8571,"cell/ l",2,NA,428571.4286,NA,247435.8297,3,0.8,349033.2934,-0.561317132,0.692923077
"2399",2399,2415,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,673469.3878,"cell/ l","abundance","biom","SS",NA,489795.9184,NA,282783.8053,3,90,NA,75,NA,428571.4286,"cell/ l",2,NA,489795.9184,NA,282783.8053,3,0.8,489795.9184,-0.4,0.68
"2400",2400,2416,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,61224.4898,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,244897.9592,"cell/ l",2,NA,244897.9592,NA,141391.9027,3,0.8,NA,NA,NA
"2401",2401,2417,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,222222.2222,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,444444.4444,"cell/ l",2,NA,259259.2593,NA,149683.4031,3,0.8,NA,NA,NA
"2402",2402,2418,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1851851.852,"cell/ l","abundance","biom","SS",NA,1148148.148,NA,662883.6424,3,90,NA,75,NA,1444444.4444,"cell/ l",2,NA,962962.963,NA,555966.9259,3,0.8,1059608.852,-0.307590792,0.674551008
"2403",2403,2419,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,814814.8148,"cell/ l","abundance","biom","SS",NA,1e+06,NA,577350.2692,3,90,NA,75,NA,629629.6296,"cell/ l",2,NA,518518.5185,NA,299366.8062,3,0.8,796511.5988,-0.185996222,0.66954955
"2404",2404,2420,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,2222222.222,"cell/ l","abundance","biom","SS",NA,1555555.556,NA,898100.4187,3,90,NA,75,NA,1037037.037,"cell/ l",2,NA,407407.4074,NA,235216.7763,3,0.8,1137043.069,-0.833871798,0.724611848
"2405",2405,2421,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1703703.704,"cell/ l","abundance","biom","SS",NA,851851.8519,NA,491816.896,3,90,NA,75,NA,2370370.3704,"cell/ l",2,NA,481481.4815,NA,277983.4629,3,0.8,691908.9516,0.770814328,0.716179561
"2406",2406,2422,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,3407407.407,"cell/ l","abundance","biom","SS",NA,888888.8889,NA,513200.2393,3,90,NA,75,NA,1296296.2963,"cell/ l",2,NA,481481.4815,NA,277983.4629,3,0.8,714824.4098,-2.362662586,1.131847875
"2407",2407,2423,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1111111.111,"cell/ l","abundance","biom","SS",NA,777777.7778,NA,449050.2094,3,90,NA,75,NA,1259259.2593,"cell/ l",2,NA,666666.6667,NA,384900.1795,3,0.8,724355.8228,0.163619198,0.668897603
"2408",2408,2424,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1962962.963,"cell/ l","abundance","biom","SS",NA,1296296.296,NA,748417.0156,3,90,NA,75,NA,1296296.2963,"cell/ l",2,NA,333333.3333,NA,192450.0897,3,0.8,946439.4325,-0.563515546,0.693129148
"2409",2409,2425,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1185185.185,"cell/ l","abundance","biom","SS",NA,333333.3333,NA,192450.0897,3,90,NA,75,NA,1629629.6296,"cell/ l",2,NA,370370.3704,NA,213833.433,3,0.8,352338.8443,1.009129596,0.751528545
"2410",2410,2426,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",15,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,851851.8519,"cell/ l","abundance","biom","SS",NA,1111111.111,NA,641500.2991,3,90,NA,75,NA,666666.6667,"cell/ l",2,NA,333333.3333,NA,192450.0897,3,0.8,820267.9478,-0.180609456,0.669384981
"2411",2411,2427,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"cryptophytes","phytoplankton",22,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,851851.8519,"cell/ l","abundance","biom","SS",NA,370370.3704,NA,213833.433,3,90,NA,75,NA,1111111.1111,"cell/ l",2,NA,444444.4444,NA,256600.1196,3,0.8,409087.4451,0.507000178,0.688087432
"2412",2412,2428,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,4382022.472,"cell/ l","abundance","biom","SS",NA,1348314.607,NA,778449.8012,3,90,NA,75,NA,3258426.9663,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2413",2413,2429,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,8202247.191,"cell/ l","abundance","biom","SS",NA,2921348.315,NA,1686641.236,3,90,NA,75,NA,4157303.3708,"cell/ l",2,NA,898876.4045,NA,518966.5341,3,0.8,2161279.108,-1.497240705,0.853477477
"2414",2414,2430,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,13820224.72,"cell/ l","abundance","biom","SS",NA,9213483.146,NA,5319406.975,3,90,NA,75,NA,4831460.6742,"cell/ l",2,NA,898876.4045,NA,518966.5341,3,0.8,6545847.939,-1.098560691,0.767236299
"2415",2415,2431,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,15168539.33,"cell/ l","abundance","biom","SS",NA,7640449.438,NA,4411215.54,3,90,NA,75,NA,4382022.4719,"cell/ l",2,NA,1797752.809,NA,1037933.068,3,0.8,5550152.375,-1.554770554,0.86810929
"2416",2416,2432,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,7528089.888,"cell/ l","abundance","biom","SS",NA,2247191.011,NA,1297416.335,3,90,NA,75,NA,2808988.764,"cell/ l",2,NA,1123595.506,NA,648708.1676,3,0.8,1776560.483,-2.125050588,1.042986667
"2417",2417,2433,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,3707865.169,"cell/ l","abundance","biom","SS",NA,2471910.112,NA,1427157.969,3,90,NA,75,NA,2584269.6629,"cell/ l",2,NA,224719.1011,NA,129741.6335,3,0.8,1755112.287,-0.51214752,0.68852459
"2418",2418,2434,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,3932584.27,"cell/ l","abundance","biom","SS",NA,2022471.91,NA,1167674.702,3,90,NA,75,NA,1685393.2584,"cell/ l",2,NA,674157.3034,NA,389224.9006,3,0.8,1507461.558,-1.192569588,0.785185185
"2419",2419,2435,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,3820224.719,"cell/ l","abundance","biom","SS",NA,2359550.562,NA,1362287.152,3,90,NA,75,NA,1460674.1573,"cell/ l",2,NA,898876.4045,NA,518966.5341,3,0.8,1785421.189,-1.057252183,0.759815182
"2420",2420,2436,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,5280898.876,"cell/ l","abundance","biom","SS",NA,898876.4045,NA,518966.5341,3,90,NA,75,NA,1460674.1573,"cell/ l",2,NA,674157.3034,NA,389224.9006,3,0.8,794502.0013,-3.84666089,1.899733333
"2421",2421,2437,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,4831460.674,"cell/ l","abundance","biom","SS",NA,2022471.91,NA,1167674.702,3,90,NA,75,NA,2134831.4607,"cell/ l",2,NA,674157.3034,NA,389224.9006,3,0.8,1507461.558,-1.431083506,0.837333333
"2422",2422,2438,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,10898876.4,"cell/ l","abundance","biom","SS",NA,14382022.47,NA,8303464.546,3,90,NA,75,NA,3033707.8652,"cell/ l",2,NA,1348314.607,NA,778449.8012,3,0.8,10214218.59,-0.616017249,0.698289771
"2423",2423,2439,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,6404494.382,"cell/ l","abundance","biom","SS",NA,8764044.944,NA,5059923.708,3,90,NA,75,NA,2134831.4607,"cell/ l",2,NA,1573033.708,NA,908191.4347,3,0.8,6296146.394,-0.542511264,0.691193206
"2424",2424,2440,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,4800000,"cell/ l","abundance","biom","SS",NA,1500000,NA,866025.4038,3,90,NA,75,NA,3900000,"cell/ l",2,NA,2100000,NA,1212435.565,3,0.8,1824828.759,-0.39455757,0.67963964
"2425",2425,2441,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1500000,"cell/ l","abundance","biom","SS",NA,1200000,NA,692820.323,3,90,NA,75,NA,3900000,"cell/ l",2,NA,6e+05,NA,346410.1615,3,0.8,948683.2981,2.023857703,1.008
"2426",2426,2442,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,2100000,"cell/ l","abundance","biom","SS",NA,1800000,NA,1039230.485,3,90,NA,75,NA,5400000,"cell/ l",2,NA,9e+05,NA,519615.2423,3,0.8,1423024.947,1.855202894,0.953481481
"2427",2427,2443,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1500000,"cell/ l","abundance","biom","SS",NA,9e+05,NA,519615.2423,3,90,NA,75,NA,5400000,"cell/ l",2,NA,9e+05,NA,519615.2423,3,0.8,9e+05,3.466666667,1.668148148
"2428",2428,2444,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,3300000,"cell/ l","abundance","biom","SS",NA,3300000,NA,1905255.888,3,90,NA,75,NA,8700000,"cell/ l",2,NA,4200000,NA,2424871.131,3,0.8,3776903.494,1.143794118,0.775688749
"2429",2429,2445,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,2400000,"cell/ l","abundance","biom","SS",NA,2100000,NA,1212435.565,3,90,NA,75,NA,6900000,"cell/ l",2,NA,3900000,NA,2251666.05,3,0.8,3132091.953,1.149391542,0.77675841
"2430",2430,2446,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,3300000,"cell/ l","abundance","biom","SS",NA,2100000,NA,1212435.565,3,90,NA,75,NA,9e+06,"cell/ l",2,NA,6300000,NA,3637306.696,3,0.8,4695742.753,0.971092379,0.745251701
"2431",2431,2447,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,3300000,"cell/ l","abundance","biom","SS",NA,1800000,NA,1039230.485,3,90,NA,75,NA,8400000,"cell/ l",2,NA,5100000,NA,2944486.373,3,0.8,3824264.635,1.066871775,0.761517949
"2432",2432,2448,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,4800000,"cell/ l","abundance","biom","SS",NA,4350000,NA,2511473.671,3,90,NA,75,NA,13800000,"cell/ l",2,NA,11700000,NA,6754998.15,3,0.8,8826451.722,0.815729834,0.72211793
"2433",2433,2449,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,6900000,"cell/ l","abundance","biom","SS",NA,5700000,NA,3290896.534,3,90,NA,75,NA,18300000,"cell/ l",2,NA,12900000,NA,7447818.473,3,0.8,9972462.083,0.914518393,0.736361991
"2434",2434,2450,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",15,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,5100000,"cell/ l","abundance","biom","SS",NA,3900000,NA,2251666.05,3,90,NA,75,NA,20400000,"cell/ l",2,NA,10800000,NA,6235382.907,3,0.8,8119421.162,1.507496625,0.856045506
"2435",2435,2451,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"picoeukaryotes","phytoplankton",22,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,3e+06,"cell/ l","abundance","biom","SS",NA,1200000,NA,692820.323,3,90,NA,75,NA,5700000,"cell/ l",2,NA,2700000,NA,1558845.727,3,0.8,2089258.242,1.033859748,0.755738832
"2436",2436,2452,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,3134328.358,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,2686567.1642,"cell/ l",2,NA,1343283.582,NA,775545.1377,3,0.8,NA,NA,NA
"2437",2437,2453,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,4253731.343,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,3582089.5522,"cell/ l",2,NA,1343283.582,NA,775545.1377,3,0.8,NA,NA,NA
"2438",2438,2454,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,5597014.925,"cell/ l","abundance","biom","SS",NA,1343283.58,NA,775545.1365,3,90,NA,75,NA,4477611.9403,"cell/ l",2,NA,671641.791,NA,387772.5689,3,0.8,1061958.914,-0.843274044,0.725925926
"2439",2439,2455,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,6044776.119,"cell/ l","abundance","biom","SS",NA,1791044.78,NA,1034060.186,3,90,NA,75,NA,4253731.3433,"cell/ l",2,NA,1119402.985,NA,646287.6148,3,0.8,1493469.86,-0.95940056,0.743370786
"2440",2440,2456,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,3805970.149,"cell/ l","abundance","biom","SS",NA,1343283.58,NA,775545.1365,3,90,NA,75,NA,1567164.1791,"cell/ l",2,NA,895522.3881,NA,517030.0918,3,0.8,1141571.532,-1.568929083,0.871794872
"2441",2441,2457,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,5820895.522,"cell/ l","abundance","biom","SS",NA,6268656.72,NA,3619210.645,3,90,NA,75,NA,1119402.9851,"cell/ l",2,NA,1119402.985,NA,646287.6148,3,0.8,4502728.068,-0.835314497,0.724812526
"2442",2442,2458,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,4701492.537,"cell/ l","abundance","biom","SS",NA,3134328.36,NA,1809605.322,3,90,NA,75,NA,3582089.5522,"cell/ l",2,NA,1343283.582,NA,775545.1377,3,0.8,2411267.825,-0.371390676,0.67816092
"2443",2443,2459,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,6940298.507,"cell/ l","abundance","biom","SS",NA,2462686.57,NA,1421832.754,3,90,NA,75,NA,3805970.1493,"cell/ l",2,NA,1567164.179,NA,904802.6607,3,0.8,2064077.119,-1.214810563,0.789647059
"2444",2444,2460,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,9626865.672,"cell/ l","abundance","biom","SS",NA,9402985.07,NA,5428815.961,3,90,NA,75,NA,5149253.7313,"cell/ l",2,NA,2686567.164,NA,1551090.275,3,0.8,6914975.465,-0.518019127,0.689028651
"2445",2445,2461,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,4477611.94,"cell/ l","abundance","biom","SS",NA,1119402.99,NA,646287.6176,3,90,NA,75,NA,12985074.6269,"cell/ l",2,NA,7388059.701,NA,4265498.257,3,0.8,5283771.816,1.28808934,0.804931179
"2446",2446,2462,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,3582089.552,"cell/ l","abundance","biom","SS",NA,2686567.16,NA,1551090.273,3,90,NA,75,NA,2910447.7612,"cell/ l",2,NA,2462686.567,NA,1421832.752,3,0.8,2577059.199,-0.208498677,0.670289308
"2447",2447,2463,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,3358208.955,"cell/ l","abundance","biom","SS",NA,3805970.15,NA,2197377.891,3,90,NA,75,NA,2462686.5672,"cell/ l",2,NA,2238805.97,NA,1292575.23,3,0.8,3122311.72,-0.229451117,0.671053985
"2448",2448,2464,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,1207977.208,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,619943.0199,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2449",2449,2465,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1827920.228,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,1228490.0285,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2450",2450,2466,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1258119.658,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,1850712.2507,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2451",2451,2467,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1868945.869,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,1871225.0712,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2452",2452,2468,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1948717.949,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,1941880.3419,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2453",2453,2469,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1966951.567,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,1966951.567,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2454",2454,2470,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,804558.4046,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,1399430.1994,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2455",2455,2471,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,825071.2251,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,2014814.8148,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2456",2456,2472,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,1445014.245,"cell/ l","abundance","biom","SS",NA,NA,NA,NA,3,90,NA,75,NA,6185754.9858,"cell/ l",2,NA,6520797.721,NA,3764784.319,3,0.8,NA,NA,NA
"2457",2457,2473,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,920797.7208,"cell/ l","abundance","biom","SS",NA,4743019.943,NA,2738383.841,3,90,NA,75,NA,25814245.0142,"cell/ l",2,NA,21925925.93,NA,12658939.24,3,0.8,15862573.34,1.255455682,0.798014081
"2458",2458,2474,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",15,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,948148.1481,"cell/ l","abundance","biom","SS",NA,7111111.111,NA,4105601.914,3,90,NA,75,NA,38874074.0741,"cell/ l",2,NA,29037037.04,NA,16764541.15,3,0.8,21139032.87,1.435294648,0.838339227
"2459",2459,2475,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"nanoeukaryotes","phytoplankton",22,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,14151566.95,"cell/ l","abundance","biom","SS",NA,3553276.353,NA,2051485.059,3,90,NA,75,NA,8815954.416,"cell/ l",2,NA,6520797.721,NA,3764784.319,3,0.8,5251027.317,-0.812886655,0.721732059
"2460",2460,2476,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.823,NA,34.41,0.25,3.5,NA,NA,3.08,3,120,NA,100,NA,537313.4328,"cell/ l","abundance","biom","SS",NA,67164.1791,NA,38777.25689,3,90,NA,75,NA,447761.194,"cell/ l",2,NA,111940.2985,NA,64628.76148,3,0.8,92308.3349,-0.776114,0.716862745
"2461",2461,2477,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,940298.5075,"cell/ l","abundance","biom","SS",NA,89552.23881,NA,51703.00918,3,90,NA,75,NA,671641.791,"cell/ l",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2462",2462,2478,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1522388.06,"cell/ l","abundance","biom","SS",NA,313432.8358,NA,180960.5321,3,90,NA,75,NA,694029.8507,"cell/ l",2,NA,291044.7761,NA,168034.7798,3,0.8,302446.0318,-2.191090302,1.066739726
"2463",2463,2479,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,2059701.493,"cell/ l","abundance","biom","SS",NA,313432.8358,NA,180960.5321,3,90,NA,75,NA,649253.7313,"cell/ l",2,NA,380597.0149,NA,219737.789,3,0.8,348636.0784,-3.236492947,1.539573883
"2464",2464,2480,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1723880.597,"cell/ l","abundance","biom","SS",NA,514925.3731,NA,297292.3028,3,90,NA,75,NA,380597.0149,"cell/ l",2,NA,313432.8358,NA,180960.5321,3,0.8,426255.9574,-2.521083511,1.196321839
"2465",2465,2481,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,1276119.403,"cell/ l","abundance","biom","SS",NA,358208.9552,NA,206812.0367,3,90,NA,75,NA,358208.9552,"cell/ l",2,NA,313432.8358,NA,180960.5321,3,0.8,336566.3368,-2.181823545,1.063362832
"2466",2466,2482,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,985074.6269,"cell/ l","abundance","biom","SS",NA,358208.9552,NA,206812.0367,3,90,NA,75,NA,268656.7164,"cell/ l",2,NA,246268.6567,NA,142183.2752,3,0.8,307377.5422,-1.864594024,0.956392573
"2467",2467,2483,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,425373.1343,"cell/ l","abundance","biom","SS",NA,156716.4179,NA,90480.26607,3,90,NA,75,NA,156716.4179,"cell/ l",2,NA,134328.3582,NA,77554.51377,3,0.8,145952.2927,-1.472572779,0.847372549
"2468",2468,2484,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,537313.4328,"cell/ l","abundance","biom","SS",NA,470149.2537,NA,271440.7982,3,90,NA,75,NA,156716.4179,"cell/ l",2,NA,89552.23881,NA,51703.00918,3,0.8,338422.7565,-0.899696034,0.73412108
"2469",2469,2485,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,NA,NA,NA,NA,NA,0,120,NA,100,NA,447761.194,"cell/ l","abundance","biom","SS",NA,268656.7164,NA,155109.0275,3,90,NA,75,NA,134328.3582,"cell/ l",2,NA,67164.1791,NA,38777.25689,3,0.8,195815.5487,-1.280522769,0.803311547
"2470",2470,2486,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",13,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,335820.8955,"cell/ l","abundance","biom","SS",NA,134328.3582,NA,77554.51377,3,90,NA,75,NA,111940.2985,"cell/ l",2,NA,44776.1194,NA,25851.50459,3,0.8,100122.4468,-1.788854382,0.933333333
"2471",2471,2487,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp 1",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.875,NA,34.41,0.32,1.06,NA,NA,1.48,3,120,NA,100,NA,358208.9552,"cell/ l","abundance","biom","SS",NA,246268.6567,NA,142183.2752,3,90,NA,75,NA,111940.2985,"cell/ l",2,NA,67164.1791,NA,38777.25689,3,0.8,180498.3078,-1.091505664,0.765948718
"2472",2472,2488,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.85,NA,34.32,0.1,3.4,NA,NA,1.85,3,120,NA,100,NA,59449.06386,"cell/ l","abundance","biom","SS",NA,73477.00662,NA,42421.96955,3,90,NA,75,NA,132982.6348,"cell/ l",2,NA,44063.57826,NA,25440.11877,3,0.8,60582.46211,0.971021228,0.745240185
"2473",2473,2489,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,60071.271,"cell/ l","abundance","biom","SS",NA,88183.7208,NA,50912.89494,3,90,NA,75,NA,89371.5708,"cell/ l",2,NA,58826.85672,NA,33963.70156,3,0.8,74956.54636,0.312717714,0.674816031
"2474",2474,2490,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,148933.7632,"cell/ l","abundance","biom","SS",NA,117597.1492,NA,67894.74572,3,90,NA,75,NA,207704.0557,"cell/ l",2,NA,88183.7208,NA,50912.89494,3,0.8,103936.1778,0.452356773,0.683718887
"2475",2475,2491,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,31845.69263,"cell/ l","abundance","biom","SS",NA,58770.29244,NA,33931.04416,3,90,NA,75,NA,193562.9843,"cell/ l",2,NA,102946.9993,NA,59436.47774,3,0.8,83821.33359,1.543447567,0.865185866
"2476",2476,2492,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,62956.04955,"cell/ l","abundance","biom","SS",NA,44063.57826,NA,25440.11877,3,90,NA,75,NA,180609.763,"cell/ l",2,NA,88240.28508,NA,50945.55235,3,0.8,69742.19254,1.349584338,0.818448157
"2477",2477,2493,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,63465.12812,"cell/ l","abundance","biom","SS",NA,44233.27111,NA,25538.09098,3,90,NA,75,NA,181231.9701,"cell/ l",2,NA,58826.85672,NA,33963.70156,3,0.8,52044.12236,1.81026155,0.939753907
"2478",2478,2494,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",9,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,64143.89954,"cell/ l","abundance","biom","SS",NA,73533.5709,NA,42454.62696,3,90,NA,75,NA,181854.1773,"cell/ l",2,NA,73590.13519,NA,42487.28436,3,0.8,73561.85848,1.280122935,0.803226227
"2479",2479,2495,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,35352.67832,"cell/ l","abundance","biom","SS",NA,73533.5709,NA,42454.62696,3,90,NA,75,NA,153006.3918,"cell/ l",2,NA,58883.42101,NA,33996.35897,3,0.8,66612.47375,1.412993175,0.833045809
"2480",2480,2496,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",11,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,36031.44974,"cell/ l","abundance","biom","SS",NA,205724.3057,NA,118774.9833,3,90,NA,75,NA,197635.6129,"cell/ l",2,NA,44176.70683,NA,25505.43358,3,0.8,148785.1998,0.868926013,0.729586035
"2481",2481,2497,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",14,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,NA,NA,NA,NA,NA,0,120,NA,100,NA,96555.23502,"cell/ l","abundance","biom","SS",NA,73477.00662,NA,42421.96955,3,90,NA,75,NA,390689.5186,"cell/ l",2,NA,191130.7201,NA,110349.3727,3,0.8,144792.6494,1.625133788,0.886754986
"2482",2482,2498,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",15,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,7.856,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,67764.0138,"cell/ l","abundance","biom","SS",NA,58770.29244,NA,33931.04416,3,90,NA,75,NA,464788.7324,"cell/ l",2,NA,235194.2983,NA,135789.4914,3,0.8,171420.9807,1.852864064,0.95275877
"2483",2483,2499,"1004","Donahue, K; Klaas, C; Dillingham, PW; Hoffmann, LJ",2018,"Combined effects of ocean acidification and increased light intensity on natural phytoplankton communities from two Southern Ocean water masses","J. Plankton Res.",1,"exp2",NA,"Fig. 6","winter","2015","Lab","culture",NA,NA,NA,"coccolithophores","phytoplankton",22,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",40,NA,11,8.594,NA,34.32,0.04,1.12,NA,NA,1.19,3,120,NA,100,NA,189433.7915,"cell/ l","abundance","biom","SS",NA,191243.8486,NA,110414.6875,3,90,NA,75,NA,409977.9399,"cell/ l",2,NA,353017.7046,NA,203814.8668,3,0.8,283897.6131,0.621475175,0.698852616
"2484",2484,2500,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,0,NA,0,NA,21.2559,"photosynthesis",1,NA,10.65088757,NA,6.149292808,3,0.8,65.71520702,-3.414969466,1.638501371
"2485",2485,2501,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,70,NA,9.333333333,NA,145.1949,"photosynthesis",1,NA,7.115894715,NA,4.108363729,3,0.8,65.47584066,-1.91313667,0.971674327
"2486",2486,2502,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,220,NA,29.33333333,NA,442.7311,"photosynthesis",1,NA,10.65088757,NA,6.149292808,3,0.8,65.71520702,1.715961145,0.912043554
"2487",2487,2503,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,375,NA,50,NA,591.1243,"photosynthesis",1,NA,74.55621302,NA,43.04504966,3,0.8,83.91115648,2.758623521,1.300833644
"2488",2488,2504,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,450,NA,60,NA,569.4705,"photosynthesis",1,NA,63.90532544,NA,36.89575685,3,0.8,79.39592585,2.697320956,1.272961695
"2489",2489,2505,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,550,NA,73.33333333,NA,629.2899,"photosynthesis",1,NA,53.25443787,NA,30.74646404,3,0.8,75.36435038,3.476601775,1.673896659
"2490",2490,2506,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,301.7751479,"photosynthesis","productivity","phys","dQ",NA,92.32299531,NA,53.30270619,3,650,NA,86.66666667,NA,486.819,"photosynthesis",1,NA,67.4556213,NA,38.94552112,3,0.8,80.85108629,1.830959875,0.946034505
"2491",2491,2507,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,0,NA,0,NA,17.7056,"photosynthesis",1,NA,7.115894715,NA,4.108363729,3,0.8,11.23186468,-5.061822319,2.801837099
"2492",2492,2508,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,70,NA,9.333333333,NA,42.2363,"photosynthesis",1,NA,14.21648643,NA,8.207892268,3,0.8,14.20883699,-2.620139631,1.238760974
"2493",2493,2509,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,220,NA,29.33333333,NA,98.3524,"photosynthesis",1,NA,14.18588043,NA,8.190221886,3,0.8,14.19353399,0.539946013,0.690961808
"2494",2494,2510,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,375,NA,50,NA,55.0296,"photosynthesis",1,NA,7.100591716,NA,4.099528539,3,0.8,11.22702128,-2.404421462,1.148436881
"2495",2495,2511,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,450,NA,60,NA,200.2397,"photosynthesis",1,NA,35.50295858,NA,20.49764269,3,0.8,27.03824771,3.298055369,1.573097435
"2496",2496,2512,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,550,NA,73.33333333,NA,103.8462,"photosynthesis",1,NA,28.40236686,NA,16.39811415,3,0.8,22.45404256,0.537041982,0.690701174
"2497",2497,2513,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,88.77269945,"photosynthesis","productivity","phys","dQ",NA,14.20118343,NA,8.199057077,3,650,NA,86.66666667,NA,153.1065,"photosynthesis",1,NA,24.83676801,NA,14.33951469,3,0.8,20.23040603,2.544044221,1.206013417
"2498",2498,2514,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106383,NA,1.781187001,3,0,NA,0,NA,6.0638,"calcification rate",1,NA,0.638297872,NA,0.368521448,3,0.8,2.227701233,-4.164201019,2.111714177
"2499",2499,2515,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106383,NA,1.781187001,3,70,NA,9.333333333,NA,6.8085,"calcification rate",1,NA,1.063829787,NA,0.614202414,3,0.8,2.307554464,-3.761926836,1.846007793
"2500",2500,2516,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106,NA,1.78118678,3,220,NA,29.33333333,NA,12.9787,"calcification rate",1,NA,4.14893617,NA,2.395389415,3,0.8,3.655923302,-1.024277738,0.754095407
"2501",2501,2517,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106,NA,1.78118678,3,375,NA,50,NA,17.766,"calcification rate",1,NA,4.468085106,NA,2.579650139,3,0.8,3.839379087,0.022166705,0.666707614
"2502",2502,2518,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106,NA,1.78118678,3,450,NA,60,NA,19.0426,"calcification rate",1,NA,3.510638298,NA,2.026867966,3,0.8,3.304728453,0.334787864,0.676006909
"2503",2503,2519,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106,NA,1.78118678,3,550,NA,73.33333333,NA,21.1702,"calcification rate",1,NA,1.276595745,NA,0.737042897,3,0.8,2.360887092,1.189599726,0.784595626
"2504",2504,2520,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,25,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,17.65957447,"calcification rate","productivity","phys","dQ",NA,3.085106,NA,1.78118678,3,650,NA,86.66666667,NA,19.0426,"calcification rate",1,NA,2.659574468,NA,1.535506035,3,0.8,2.880209661,0.384132792,0.678963167
"2505",2505,2521,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425531915,NA,0.245680966,3,0,NA,0,NA,0.7447,"calcification rate",1,NA,0.319148936,NA,0.184260724,3,0.8,0.376120628,-2.94156421,1.387733333
"2506",2506,2522,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425532,NA,0.245681015,3,70,NA,9.333333333,NA,0.6383,"calcification rate",1,NA,0.212765957,NA,0.122840483,3,0.8,0.336412571,-3.541750413,1.711999665
"2507",2507,2523,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425532,NA,0.245681015,3,220,NA,29.33333333,NA,1.4894,"calcification rate",1,NA,0.212765957,NA,0.122840483,3,0.8,0.336412571,-1.517893034,0.858666605
"2508",2508,2524,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425532,NA,0.245681015,3,375,NA,50,NA,1.7021,"calcification rate",1,NA,0.319148936,NA,0.184260724,3,0.8,0.376120676,-0.905096564,0.734933316
"2509",2509,2525,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425532,NA,0.245681015,3,450,NA,60,NA,3.0851,"calcification rate",1,NA,0.957446809,NA,0.552782173,3,0.8,0.740871741,1.033859714,0.755738826
"2510",2510,2526,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425532,NA,0.245681015,3,550,NA,73.33333333,NA,2.234,"calcification rate",1,NA,0.638297872,NA,0.368521448,3,0.8,0.542448918,0.156892898,0.668717948
"2511",2511,2527,"1005","Liu, HJ; Zhang, XD; Sun, J; Satheeswaran, T; Zhang, GC; Li, HB; An, XL",2019,"Morphology, phylogenetic position, and ecophysiological features of the coccolithophore Chrysotila dentata (Prymnesiophyceae) isolated from the Bohai Sea, China","Phycologia",1,"gradient of eight irradiances, Photosynthesis  and calcification as response",NA,"FIG. 17",NA,NA,"Lab","seawater",NA,NA,"Bohai Sea","Chrysotila dentata","phytoplankton",1,"microcosm","culture flask",0.03,NA,"No","temp","gradient","12",40,NA,13,NA,NA,NA,NA,NA,NA,NA,NA,0,750,NA,100,NA,2.127659574,"calcification rate","productivity","phys","dQ",NA,0.425532,NA,0.245681015,3,650,NA,86.66666667,NA,2.4468,"calcification rate",1,NA,0.638297872,NA,0.368521448,3,0.8,0.542448918,0.470678695,0.685128203
"2512",2512,2528,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,59.40594059,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,25,NA,2.5,NA,68.3168,"Chla  (pg cell)",1,NA,10.28941074,NA,5.940594059,3,0.8,9.094640134,0.783836718,0.717866667
"2513",2513,2529,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,63.86138614,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,25,NA,2.5,NA,84.6535,"Chla  (pg cell)",1,NA,23.15117415,NA,13.36633663,3,0.8,17.25586639,0.963942522,0.744098765
"2514",2514,2530,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,90.59405941,"Chla  (pg cell)","cellular content","phys","Q",NA,18.00646878,NA,10.3960396,3,25,NA,2.5,NA,68.3168,"Chla  (pg cell)",1,NA,7.717058054,NA,4.455445545,3,0.8,13.85254314,-1.286535043,0.804597701
"2515",2515,2531,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,59.40594059,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,85,NA,8.5,NA,35.6436,"Chla  (pg cell)",1,NA,15.43411611,NA,8.910891089,3,0.8,12.20174014,-1.557966385,0.868938271
"2516",2516,2532,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,63.86138614,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,85,NA,8.5,NA,47.5248,"Chla  (pg cell)",1,NA,18.00646878,NA,10.3960396,3,0.8,13.85254314,-0.943459031,0.740842912
"2517",2517,2533,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,90.59405941,"Chla  (pg cell)","cellular content","phys","Q",NA,18.00646878,NA,10.3960396,3,85,NA,8.5,NA,59.4059,"Chla  (pg cell)",1,NA,18.00646878,NA,10.3960396,3,0.8,18.00646878,-1.385640647,0.826666667
"2518",2518,2534,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,59.40594059,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,200,NA,20,NA,38.6139,"Chla  (pg cell)",1,NA,7.717058054,NA,4.455445545,3,0.8,7.717058054,-2.155441004,1.05382716
"2519",2519,2535,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,63.86138614,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,200,NA,20,NA,50.495,"Chla  (pg cell)",1,NA,5.14470537,NA,2.97029703,3,0.8,6.558238268,-1.63047893,0.888205128
"2520",2520,2536,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,90.59405941,"Chla  (pg cell)","cellular content","phys","Q",NA,18.00646878,NA,10.3960396,3,200,NA,20,NA,65.3465,"Chla  (pg cell)",1,NA,7.717058054,NA,4.455445545,3,0.8,13.85254314,-1.458073048,0.843831418
"2521",2521,2537,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,47.52475248,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,25,NA,2.5,NA,87.6238,"Chla  (pg cell)",1,NA,7.717058054,NA,4.455445545,3,0.8,7.717058054,4.156921938,2.106666666
"2522",2522,2538,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,53.46534653,"Chla  (pg cell)","cellular content","phys","Q",NA,15.43411611,NA,8.910891089,3,25,NA,2.5,NA,86.1386,"Chla  (pg cell)",1,NA,7.717058054,NA,4.455445545,3,0.8,12.20174014,2.142203781,1.04908642
"2523",2523,2539,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,54.95049505,"Chla  (pg cell)","cellular content","phys","Q",NA,10.28941074,NA,5.940594059,3,25,NA,2.5,NA,75.7426,"Chla  (pg cell)",1,NA,12.86176342,NA,7.425742574,3,0.8,11.64682213,1.428171837,0.836639566
"2524",2524,2540,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,47.52475248,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,85,NA,8.5,NA,38.6139,"Chla  (pg cell)",1,NA,5.14470537,NA,2.97029703,3,0.8,6.558238268,-1.086985953,0.765128205
"2525",2525,2541,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,53.46534653,"Chla  (pg cell)","cellular content","phys","Q",NA,15.43411611,NA,8.910891089,3,85,NA,8.5,NA,32.6733,"Chla  (pg cell)",1,NA,5.14470537,NA,2.97029703,3,0.8,11.50391093,-1.445913782,0.840888889
"2526",2526,2542,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,54.95049505,"Chla  (pg cell)","cellular content","phys","Q",NA,10.28941074,NA,5.940594059,3,85,NA,8.5,NA,46.0396,"Chla  (pg cell)",1,NA,12.86176342,NA,7.425742574,3,0.8,11.64682213,-0.612073645,0.697886179
"2527",2527,2543,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,47.52475248,"Chla  (pg cell)","cellular content","phys","Q",NA,7.717058054,NA,4.455445545,3,200,NA,20,NA,38.6139,"Chla  (pg cell)",1,NA,12.86176342,NA,7.425742574,3,0.8,10.60608182,-0.67213444,0.704313725
"2528",2528,2544,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,53.46534653,"Chla  (pg cell)","cellular content","phys","Q",NA,15.43411611,NA,8.910891089,3,200,NA,20,NA,62.3762,"Chla  (pg cell)",1,NA,20.57882148,NA,11.88118812,3,0.8,18.18928027,0.391918359,0.679466667
"2529",2529,2545,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,54.95049505,"Chla  (pg cell)","cellular content","phys","Q",NA,10.28941074,NA,5.940594059,3,200,NA,20,NA,57.9208,"Chla  (pg cell)",1,NA,12.86176342,NA,7.425742574,3,0.8,11.64682213,0.204024548,0.670135501
"2530",2530,2546,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,77.22772277,"Chla  (pg cell)","cellular content","phys","Q",NA,28.29587952,NA,16.33663366,3,25,NA,2.5,NA,255.4455,"Chla  (pg cell)",1,NA,15.43411611,NA,8.910891089,3,0.8,22.79110285,6.255698042,3.927813166
"2531",2531,2547,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,118.8118812,"Chla  (pg cell)","cellular content","phys","Q",NA,46.30234833,NA,26.73267327,3,25,NA,2.5,NA,252.4752,"Chla  (pg cell)",1,NA,61.73646443,NA,35.64356436,3,0.8,54.56784081,1.959591793,0.986666666
"2532",2532,2548,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,115.8415842,"Chla  (pg cell)","cellular content","phys","Q",NA,12.86176342,NA,7.425742574,3,25,NA,2.5,NA,233.1683,"Chla  (pg cell)",1,NA,33.44058489,NA,19.30693069,3,0.8,25.3347358,3.704849611,1.810492553
"2533",2533,2549,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,77.22772277,"Chla  (pg cell)","cellular content","phys","Q",NA,28.29587952,NA,16.33663366,3,85,NA,8.5,NA,236.1386,"Chla  (pg cell)",1,NA,56.59175906,NA,32.67326733,3,0.8,44.73971386,2.841518238,1.339518825
"2534",2534,2550,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,118.8118812,"Chla  (pg cell)","cellular content","phys","Q",NA,46.30234833,NA,26.73267327,3,85,NA,8.5,NA,191.5842,"Chla  (pg cell)",1,NA,48.874701,NA,28.21782178,3,0.8,47.60590225,1.222911845,0.791292782
"2535",2535,2551,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,115.8415842,"Chla  (pg cell)","cellular content","phys","Q",NA,12.86176342,NA,7.425742574,3,85,NA,8.5,NA,190.099,"Chla  (pg cell)",1,NA,36.01293759,NA,20.79207921,3,0.8,27.0403091,2.196940144,1.068878833
"2536",2536,2552,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,77.22772277,"Chla  (pg cell)","cellular content","phys","Q",NA,28.29587952,NA,16.33663366,3,200,NA,20,NA,80.198,"Chla  (pg cell)",1,NA,20.57882148,NA,11.88118812,3,0.8,24.74009591,0.096048036,0.667435435
"2537",2537,2553,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,118.8118812,"Chla  (pg cell)","cellular content","phys","Q",NA,46.30234833,NA,26.73267327,3,200,NA,20,NA,145.5446,"Chla  (pg cell)",1,NA,10.28941074,NA,5.940594059,3,0.8,33.53937562,0.637642718,0.70054902
"2538",2538,2554,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,115.8415842,"Chla  (pg cell)","cellular content","phys","Q",NA,12.86176342,NA,7.425742574,3,200,NA,20,NA,130.6931,"Chla  (pg cell)",1,NA,12.86176342,NA,7.425742574,3,0.8,12.86176342,0.923760428,0.737777777
"2539",2539,2555,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,60.89108911,"Chla  (pg cell)","cellular content","phys","Q",NA,51.4470537,NA,29.7029703,3,25,NA,2.5,NA,231.6832,"Chla  (pg cell)",1,NA,38.58529026,NA,22.27722772,3,0.8,45.47320067,3.004707417,1.419022222
"2540",2540,2556,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,123.2673267,"Chla  (pg cell)","cellular content","phys","Q",NA,64.30881711,NA,37.12871287,3,25,NA,2.5,NA,224.2574,"Chla  (pg cell)",1,NA,36.01293759,NA,20.79207921,3,0.8,52.11792221,1.550178437,0.866921099
"2541",2541,2557,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,161.8811881,"Chla  (pg cell)","cellular content","phys","Q",NA,20.57882148,NA,11.88118812,3,25,NA,2.5,NA,219.802,"Chla  (pg cell)",1,NA,43.72999563,NA,25.24752475,3,0.8,34.17455495,1.355881115,0.8198678
"2542",2542,2558,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,60.89108911,"Chla  (pg cell)","cellular content","phys","Q",NA,51.4470537,NA,29.7029703,3,85,NA,8.5,NA,236.1386,"Chla  (pg cell)",1,NA,64.30881711,NA,37.12871287,3,0.8,58.23411067,2.407489669,1.149667209
"2543",2543,2559,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,123.2673267,"Chla  (pg cell)","cellular content","phys","Q",NA,64.30881711,NA,37.12871287,3,85,NA,8.5,NA,239.1089,"Chla  (pg cell)",1,NA,66.8811698,NA,38.61386139,3,0.8,65.60760182,1.412538559,0.832938765
"2544",2544,2560,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,161.8811881,"Chla  (pg cell)","cellular content","phys","Q",NA,20.57882148,NA,11.88118812,3,85,NA,8.5,NA,282.1782,"Chla  (pg cell)",1,NA,72.02587517,NA,41.58415842,3,0.8,52.96798367,1.816901779,0.941761006
"2545",2545,2561,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,60.89108911,"Chla  (pg cell)","cellular content","phys","Q",NA,51.4470537,NA,29.7029703,3,200,NA,20,NA,93.5644,"Chla  (pg cell)",1,NA,23.15117415,NA,13.36633663,3,0.8,39.892206,0.655231096,0.702443982
"2546",2546,2562,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,123.2673267,"Chla  (pg cell)","cellular content","phys","Q",NA,64.30881711,NA,37.12871287,3,200,NA,20,NA,160.396,"Chla  (pg cell)",1,NA,33.44058489,NA,19.30693069,3,0.8,51.25376414,0.579527588,0.694654352
"2547",2547,2563,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,161.8811881,"Chla  (pg cell)","cellular content","phys","Q",NA,20.57882148,NA,11.88118812,3,200,NA,20,NA,111.3861,"Chla  (pg cell)",1,NA,102.8941074,NA,59.40594059,3,0.8,74.19799602,-0.544435723,0.691367521
"2548",2548,2564,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.557142857,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.725,"Fv/Fm",1,NA,0.012371791,NA,0.007142857,3,0.8,0.012371794,10.85418289,10.48444052
"2549",2549,2565,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.564285714,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.7321,"Fv/Fm",1,NA,0.012371791,NA,0.007142857,3,0.8,0.012371794,10.85418289,10.48444052
"2550",2550,2566,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.489285714,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,25,NA,2.5,NA,0.7357,"Fv/Fm",1,NA,0.024743583,NA,0.014285714,3,0.8,0.024743579,7.96743491,5.956668254
"2551",2551,2567,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.557142857,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.7464,"Fv/Fm",1,NA,0.015464739,NA,0.008928571,3,0.8,0.014003919,10.81329937,10.41062026
"2552",2552,2568,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.564285714,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.7321,"Fv/Fm",1,NA,0.012371791,NA,0.007142857,3,0.8,0.012371794,10.85418289,10.48444052
"2553",2553,2569,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.489285714,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,85,NA,8.5,NA,0.7607,"Fv/Fm",1,NA,0.012371791,NA,0.007142857,3,0.8,0.019561515,11.10051316,10.93511604
"2554",2554,2570,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.557142857,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6214,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,4.156920275,2.106665515
"2555",2555,2571,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.564285714,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6107,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,3.002220199,1.417777177
"2556",2556,2572,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.489285714,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,200,NA,20,NA,0.6143,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,4.041453097,2.027778594
"2557",2557,2573,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.557142857,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.725,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,10.85418072,10.48443659
"2558",2558,2574,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.564285714,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.725,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,10.39230069,9.666659467
"2559",2559,2575,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.489285714,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,25,NA,2.5,NA,0.7214,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,7.505555751,5.361113928
"2560",2560,2576,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.557142857,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.7429,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,12.0088808,12.68443483
"2561",2561,2577,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.564285714,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.7429,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,11.54700076,11.77776889
"2562",2562,2578,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.489285714,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,85,NA,8.5,NA,0.7643,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,8.891196813,7.254448397
"2563",2563,2579,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.557142857,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6143,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,3.695040245,1.804443534
"2564",2564,2580,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.564285714,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6036,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,2.540340168,1.204444014
"2565",2565,2581,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.489285714,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,200,NA,20,NA,0.5821,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,3.0022223,1.417778228
"2566",2566,2582,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.567857143,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.7286,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,10.39230069,9.666659467
"2567",2567,2583,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.5,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.725,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,14.54922096,18.30665255
"2568",2568,2584,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.421428571,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,25,NA,2.5,NA,0.7286,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,9.930427609,8.884449375
"2569",2569,2585,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.567857143,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.6857,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,7.621020505,5.506662795
"2570",2570,2586,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.5,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.6821,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,11.77794078,12.22665742
"2571",2571,2587,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.421428571,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,85,NA,8.5,NA,0.6643,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,7.851966017,5.804447527
"2572",2572,2588,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.567857143,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6214,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,3.464100229,1.666665867
"2573",2573,2589,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.5,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.5804,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,5.196150344,2.916664867
"2574",2574,2590,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.421428571,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,200,NA,20,NA,0.5536,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,4.272393274,2.18777869
"2575",2575,2591,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.578571429,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.7286,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,9.699480643,8.506660395
"2576",2576,2592,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.528571429,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,25,NA,2.5,NA,0.7179,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,12.23982081,13.15110112
"2577",2577,2593,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.510714286,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,25,NA,2.5,NA,0.7179,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,6.697265132,4.404446687
"2578",2578,2594,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.578571429,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.7036,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,8.082900535,6.111106756
"2579",2579,2595,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.528571429,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,85,NA,8.5,NA,0.7036,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,11.31606075,11.33776924
"2580",2580,2596,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.510714286,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,85,NA,8.5,NA,0.6964,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,6.004444601,3.671112914
"2581",2581,2597,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.578571429,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6321,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,3.464100229,1.666665867
"2582",2582,2598,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.528571429,"Fv/Fm","productivity","phys","dQ",NA,0.012371796,NA,0.00714286,3,200,NA,20,NA,0.6,"Fv/Fm",1,NA,0.012371796,NA,0.00714286,3,0.8,0.012371796,4.618800306,2.444443022
"2583",2583,2599,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.510714286,"Fv/Fm","productivity","phys","dQ",NA,0.024743576,NA,0.01428571,3,200,NA,20,NA,0.6214,"Fv/Fm",1,NA,0.024743576,NA,0.01428571,3,0.8,0.024743576,3.579572743,1.734445085
"2584",2584,2600,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.795953757,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.036416185,3,25,NA,2.5,NA,0.3173,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,0.05480976,-6.985802821,4.733453421
"2585",2585,2601,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.733526012,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.052023121,3,25,NA,2.5,NA,0.3382,"growth rate",2,NA,0.027032006,NA,0.015606936,3,0.8,0.048523937,-6.518444242,4.207509611
"2586",2586,2602,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.43699422,"growth rate","biom","biom","SS",NA,0.090106689,NA,0.062427746,3,25,NA,2.5,NA,0.2445,"growth rate",2,NA,0.054064014,NA,0.031213873,3,0.8,0.074303879,-2.072414531,1.024575166
"2587",2587,2603,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.795953757,"growth rate","biom","biom","SS",NA,0.108128028,NA,0.036416185,3,85,NA,8.5,NA,0.7023,"growth rate",2,NA,0.009010669,NA,0.005202312,3,0.8,0.076723082,-0.976411435,0.746114941
"2588",2588,2604,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.733526012,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.052023121,3,85,NA,8.5,NA,0.8688,"growth rate",2,NA,0.261309399,NA,0.150867052,3,0.8,0.19008027,0.569275771,0.693672909
"2589",2589,2605,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.43699422,"growth rate","biom","biom","SS",NA,0.090106689,NA,0.062427746,3,85,NA,8.5,NA,0.7127,"growth rate",2,NA,0.144170703,NA,0.083236994,3,0.8,0.120217318,1.834827452,0.947215982
"2590",2590,2606,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.795953757,"growth rate","biom","biom","SS",NA,0.108128028,NA,0.036416185,3,200,NA,20,NA,0.7491,"growth rate",2,NA,0.027032006,NA,0.015606936,3,0.8,0.078811166,-0.475270816,0.685490196
"2591",2591,2607,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.733526012,"growth rate","biom","biom","SS",NA,0.018021337,NA,0.052023121,3,200,NA,20,NA,0.822,"growth rate",2,NA,0.099117359,NA,0.057225434,3,0.8,0.071235593,0.99320356,0.748871109
"2592",2592,2608,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.43699422,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.062427746,3,200,NA,20,NA,0.4266,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,0.05480976,-0.151865289,0.668588589
"2593",2593,2609,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.62947977,"growth rate","biom","biom","SS",NA,0.090106689,NA,0.010404624,3,25,NA,2.5,NA,0.2757,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,0.071235592,-3.972814316,1.981937799
"2594",2594,2610,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.68150289,"growth rate","biom","biom","SS",NA,0.018021337,NA,0.036416185,3,25,NA,2.5,NA,0.2965,"growth rate",2,NA,0.018021337,NA,0.010404624,3,0.8,0.018021337,-17.08956841,25.00444571
"2595",2595,2611,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.73872832,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.052023121,3,25,NA,2.5,NA,0.2653,"growth rate",2,NA,0.018021337,NA,0.010404624,3,0.8,0.046385257,-8.164842512,6.222054436
"2596",2596,2612,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.62947977,"growth rate","biom","biom","SS",NA,0.090106689,NA,0.010404624,3,85,NA,8.5,NA,0.5983,"growth rate",2,NA,0.036042677,NA,0.020809249,3,0.8,0.06862321,-0.363887076,0.67770115
"2597",2597,2613,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.68150289,"growth rate","biom","biom","SS",NA,0.018021337,NA,0.036416185,3,85,NA,8.5,NA,0.541,"growth rate",2,NA,0.063074683,NA,0.036416185,3,0.8,0.046385257,-2.422535713,1.155723273
"2598",2598,2614,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.73872832,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.052023121,3,85,NA,8.5,NA,0.6347,"growth rate",2,NA,0.018021337,NA,0.010404624,3,0.8,0.046385257,-1.79447083,0.935010463
"2599",2599,2615,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.62947977,"growth rate","biom","biom","SS",NA,0.090106689,NA,0.010404624,3,200,NA,20,NA,0.7543,"growth rate",2,NA,0.08109602,NA,0.046820809,3,0.8,0.085719834,1.165242483,0.779815837
"2600",2600,2616,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.68150289,"growth rate","biom","biom","SS",NA,0.171202711,NA,0.036416185,3,200,NA,20,NA,0.7335,"growth rate",2,NA,0.018021337,NA,0.010404624,3,0.8,0.121727435,0.341899077,0.676407915
"2601",2601,2617,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Entomoneis paludosa","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.73872832,"growth rate","biom","biom","SS",NA,0.027032006,NA,0.052023121,3,200,NA,20,NA,0.6555,"growth rate",2,NA,0.08109602,NA,0.046820809,3,0.8,0.060445404,-1.101648562,0.767802463
"2602",2602,2618,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.993641618,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.098843931,3,25,NA,2.5,NA,0.3798,"growth rate",2,NA,0.018021337,NA,0.010404624,3,0.8,0.046385257,-10.58737828,10.0077149
"2603",2603,2619,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,1.035260116,"growth rate","biom","biom","SS",NA,0.171202711,NA,0.015606936,3,25,NA,2.5,NA,0.3954,"growth rate",2,NA,0.036042677,NA,0.020809249,3,0.8,0.123712252,-4.137888575,2.093510155
"2604",2604,2620,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.998843931,"growth rate","biom","biom","SS",NA,0.027032006,NA,0.036416185,3,25,NA,2.5,NA,0.3954,"growth rate",2,NA,0.027032006,NA,0.015606936,3,0.8,0.027032006,-17.8593688,27.24642116
"2605",2605,2621,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.993641618,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.098843931,3,85,NA,8.5,NA,0.8428,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,0.05480976,-2.20204654,1.070750747
"2606",2606,2622,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,1.035260116,"growth rate","biom","biom","SS",NA,0.171202711,NA,0.015606936,3,85,NA,8.5,NA,0.8532,"growth rate",2,NA,0.072085351,NA,0.041618497,3,0.8,0.131351943,-1.108965246,0.769150326
"2607",2607,2623,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.998843931,"growth rate","biom","biom","SS",NA,0.027032006,NA,0.036416185,3,85,NA,8.5,NA,0.9572,"growth rate",2,NA,0.027032006,NA,0.015606936,3,0.8,0.027032006,-1.231680604,0.793086426
"2608",2608,2624,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.993641618,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.098843931,3,200,NA,20,NA,0.8896,"growth rate",2,NA,0.036042677,NA,0.020809249,3,0.8,0.051368717,-1.620382966,0.88547008
"2609",2609,2625,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,1.035260116,"growth rate","biom","biom","SS",NA,0.054064014,NA,0.015606936,3,200,NA,20,NA,1.0509,"growth rate",2,NA,0.072085351,NA,0.041618497,3,0.8,0.063715051,0.195959174,0.669866666
"2610",2610,2626,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NH4",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.998843931,"growth rate","biom","biom","SS",NA,0.018021337,NA,0.036416185,3,200,NA,20,NA,1.0145,"growth rate",2,NA,0.099117359,NA,0.057225434,3,0.8,0.071235593,0.175271212,0.669226666
"2611",2611,2627,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.952023121,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.031213873,3,25,NA,2.5,NA,0.3694,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,0.05480976,-8.504455596,6.693813748
"2612",2612,2628,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.905202312,"growth rate","biom","biom","SS",NA,0.054064014,NA,0.010404624,3,25,NA,2.5,NA,0.3277,"growth rate",2,NA,0.027032006,NA,0.015606936,3,0.8,0.042741356,-10.80839181,10.40177778
"2613",2613,2629,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.926011561,"growth rate","biom","biom","SS",NA,0.018021337,NA,0.036416185,3,25,NA,2.5,NA,0.3121,"growth rate",2,NA,0.036042677,NA,0.020809249,3,0.8,0.028494237,-17.23500296,25.42044391
"2614",2614,2630,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.952023121,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.031213873,3,85,NA,8.5,NA,0.4942,"growth rate",2,NA,0.036042677,NA,0.020809249,3,0.8,0.051368717,-7.129685099,4.902700801
"2615",2615,2631,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.905202312,"growth rate","biom","biom","SS",NA,0.054064014,NA,0.010404624,3,85,NA,8.5,NA,0.5202,"growth rate",2,NA,0.018021337,NA,0.010404624,3,0.8,0.040296937,-7.642687115,5.534222194
"2616",2616,2632,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","light gradient","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.926011561,"growth rate","biom","biom","SS",NA,0.018021337,NA,0.036416185,3,85,NA,8.5,NA,0.5566,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,0.034311605,-8.611993723,6.84720299
"2617",2617,2633,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,20,NA,NA,NA,1,1000,NA,100,NA,0.952023121,"growth rate","biom","biom","SS",NA,0.063074683,NA,0.031213873,3,200,NA,20,NA,1.0769,"growth rate",2,NA,0.099117359,NA,0.057225434,3,0.8,0.083074263,1.202350638,0.787137255
"2618",2618,2634,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,100,NA,NA,NA,1,1000,NA,100,NA,0.905202312,"growth rate","biom","biom","SS",NA,3.383541112,NA,0.010404624,3,200,NA,20,NA,0.9832,"growth rate",2,NA,0.027032006,NA,0.015606936,3,0.8,2.392601219,0.026091998,0.666723399
"2619",2619,2635,"1006","Berg, GM; Driscoll, S; Hayashi, K; Kudela, R",2019,"Effects of nitrogen source, concentration, and irradiance on growth rates of two diatoms endemic to northern San Francisco Bay","Aquat Biol",1,"NO3",NA,"Fig. 3",NA,"2014","Lab","estuary",NA,NA,"Suisun Bay","Thalassiosira weissflogii","phytoplankton",NA,"microcosm","culture flask",0.2,NA,"No","nut","inhibition","12",NA,NA,15.5,8.3,NA,10,NA,1000,NA,NA,NA,1,1000,NA,100,NA,0.926011561,"growth rate","biom","biom","SS",NA,3.464101615,NA,0.036416185,3,200,NA,20,NA,0.9468,"growth rate",2,NA,0.045053345,NA,0.026011561,3,0.8,2.4496969,0.006795697,0.666670515
"2620",2620,2636,"1028","Su, YY",2019,"The effect of different light regimes on pigments in Coscinodiscus granii","Photosynthesis Research",1,"red",NA,"FIG. 1",NA,NA,"Lab","culture",NA,NA,NA,"Coscinodiscus granii","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","wavelength","light reduced","16",NA,"654",20,8,NA,30,NA,NA,NA,NA,NA,0,300,NA,100,NA,63.48837209,"Chla (pg cell)","cellular content","phys","Q",NA,3.383541112,NA,1.953488372,3,100,NA,33.33333333,NA,213.907,"Chla (pg cell)",1,NA,5.075311669,NA,2.930232558,3,0.8,4.313185539,27.89930612,65.53094017
"2621",2621,2637,"1028","Su, YY",2019,"The effect of different light regimes on pigments in Coscinodiscus granii","Photosynthesis Research",1,"red-orange",NA,"FIG. 1",NA,NA,"Lab","culture",NA,NA,NA,"Coscinodiscus granii","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","wavelength","light reduced","16",NA,"617",20,8,NA,30,NA,NA,NA,NA,NA,0,300,NA,100,NA,72,"Chla (pg cell)","cellular content","phys","Q",NA,3.464101615,NA,2,3,100,NA,33.33333333,NA,160,"Chla (pg cell)",1,NA,3.464101615,NA,2,3,0.8,3.464101615,20.32272948,35.08444444
"2622",2622,2638,"1028","Su, YY",2019,"The effect of different light regimes on pigments in Coscinodiscus granii","Photosynthesis Research",1,"yellow",NA,"FIG. 1",NA,NA,"Lab","culture",NA,NA,NA,"Coscinodiscus granii","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","wavelength","light reduced","16",NA,"590",20,8,NA,30,NA,NA,NA,NA,NA,0,300,NA,100,NA,57.18309859,"Chla (pg cell)","cellular content","phys","Q",NA,5.122967178,NA,2.957746479,3,100,NA,33.33333333,NA,131.1268,"Chla (pg cell)",1,NA,3.415311452,NA,1.971830986,3,0.8,4.353684934,13.58732442,16.05128207
"2623",2623,2639,"1028","Su, YY",2019,"The effect of different light regimes on pigments in Coscinodiscus granii","Photosynthesis Research",1,"green",NA,"FIG. 1",NA,NA,"Lab","culture",NA,NA,NA,"Coscinodiscus granii","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","wavelength","light reduced","16",NA,"528",20,8,NA,30,NA,NA,NA,NA,NA,0,300,NA,100,NA,79.11627907,"Chla (pg cell)","cellular content","phys","Q",NA,3.383541112,NA,1.953488372,3,100,NA,33.33333333,NA,140.6512,"Chla (pg cell)",1,NA,3.383541112,NA,1.953488372,3,0.8,3.383541112,14.54922679,18.30666667
"2624",2624,2640,"1028","Su, YY",2019,"The effect of different light regimes on pigments in Coscinodiscus granii","Photosynthesis Research",1,"blue",NA,"FIG. 1",NA,NA,"Lab","culture",NA,NA,NA,"Coscinodiscus granii","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","wavelength","light reduced","16",NA,"455",20,8,NA,30,NA,NA,NA,NA,NA,0,300,NA,100,NA,62.29665072,"Chla (pg cell)","cellular content","phys","Q",NA,3.480676264,NA,2.009569378,3,100,NA,33.33333333,NA,229.0909,"Chla (pg cell)",1,NA,3.480676264,NA,2.009569378,3,0.8,3.480676264,38.33605787,123.1377778
"2625",2625,2641,"1028","Su, YY",2019,"The effect of different light regimes on pigments in Coscinodiscus granii","Photosynthesis Research",1,"white",NA,"FIG. 1",NA,NA,"Lab","culture",NA,NA,NA,"Coscinodiscus granii","phytoplankton",10,"microcosm","culture flask",0.05,NA,"No","wavelength","light reduced","16",NA,NA,20,8,NA,30,NA,NA,NA,NA,NA,0,300,NA,100,NA,83.04545455,"Chla (pg cell)","cellular content","phys","Q",NA,3.306642451,NA,1.909090909,3,100,NA,33.33333333,NA,104.0455,"Chla (pg cell)",1,NA,3.306642451,NA,1.909090909,3,0.8,3.306642451,5.080682369,2.817777778
"2626",2626,2642,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,605.5045872,"POC","biom","biom","SS",NA,18.34862385,NA,10.59358292,3,33,NA,9.96978852,NA,550.4587,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,29.01172165,-1.517893277,0.858666667
"2627",2627,2643,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,1100.917431,"POC","biom","biom","SS",NA,91.74311927,NA,52.9679146,3,33,NA,9.96978852,NA,788.9908,"POC",2,NA,55.04587156,NA,31.78074876,3,0.8,75.65331423,-3.2984845,1.573333333
"2628",2628,2644,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,1577.981651,"POC","biom","biom","SS",NA,110.0917431,NA,63.56149753,3,33,NA,9.96978852,NA,1137.6147,"POC",2,NA,73.39449541,NA,42.37433168,3,0.8,93.55999108,-3.765429795,1.848205128
"2629",2629,2645,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,587.1559633,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,33,NA,9.96978852,NA,568.8073,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,46.77999554,-0.313785816,0.674871795
"2630",2630,2646,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,1394.495413,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,33,NA,9.96978852,NA,935.7798,"POC",2,NA,55.04587156,NA,31.78074876,3,0.8,55.04587156,-6.666666667,4.37037037
"2631",2631,2647,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,2201.834862,"POC","biom","biom","SS",NA,91.74311927,NA,52.9679146,3,33,NA,9.96978852,NA,1522.9358,"POC",2,NA,128.440367,NA,74.15508045,3,0.8,111.6103217,-4.866210024,2.64
"2632",2632,2648,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,500,"POC","biom","biom","SS",NA,55.55555556,NA,32.07501495,3,34,NA,9.88372093,NA,500,"POC",2,NA,55.55555556,NA,32.07501495,3,0.8,55.55555556,0,0.666666667
"2633",2633,2649,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,1203.703704,"POC","biom","biom","SS",NA,55.55555556,NA,32.07501495,3,34,NA,9.88372093,NA,833.3333,"POC",2,NA,37.03703704,NA,21.3833433,3,0.8,47.21314364,-6.275716324,3.948717949
"2634",2634,2650,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,1481.481481,"POC","biom","biom","SS",NA,203.7037037,NA,117.6083882,3,34,NA,9.88372093,NA,1129.6296,"POC",2,NA,37.03703704,NA,21.3833433,3,0.8,146.4017435,-1.922664817,0.97472
"2635",2635,2651,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,518.5185185,"POC","biom","biom","SS",NA,55.55555556,NA,32.07501495,3,34,NA,9.88372093,NA,481.4815,"POC",2,NA,37.03703704,NA,21.3833433,3,0.8,47.21314364,-0.627571632,0.699487179
"2636",2636,2652,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,1370.37037,"POC","biom","biom","SS",NA,37.03703704,NA,21.3833433,3,34,NA,9.88372093,NA,888.8889,"POC",2,NA,18.51851852,NA,10.69167165,3,0.8,29.28034871,-13.15507507,15.088
"2637",2637,2653,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,2203.703704,"POC","biom","biom","SS",NA,55.55555556,NA,32.07501495,3,34,NA,9.88372093,NA,1555.5556,"POC",2,NA,129.6296296,NA,74.84170156,3,0.8,99.72527421,-5.199469469,2.91954023
"2638",2638,2654,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,458.7155963,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,51,NA,9.9609375,NA,440.367,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,46.77999554,-0.313785816,0.674871795
"2639",2639,2655,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,899.0825688,"POC","biom","biom","SS",NA,91.74311927,NA,52.9679146,3,51,NA,9.9609375,NA,660.5505,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,69.86947804,-2.731173803,1.288275862
"2640",2640,2656,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,1211.009174,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,51,NA,9.9609375,NA,788.9908,"POC",2,NA,73.39449541,NA,42.37433168,3,0.8,64.87218176,-5.20430591,2.923733333
"2641",2641,2657,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,458.7155963,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,51,NA,9.9609375,NA,440.367,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,46.77999554,-0.313785816,0.674871795
"2642",2642,2658,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,1192.66055,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,51,NA,9.9609375,NA,715.5963,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,46.77999554,-8.158431222,6.213333333
"2643",2643,2659,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,1669.724771,"POC","biom","biom","SS",NA,201.8348624,NA,116.5294121,3,51,NA,9.9609375,NA,935.7798,"POC",2,NA,91.74311927,NA,52.9679146,3,0.8,156.7707109,-3.74531671,1.835616438
"2644",2644,2660,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,458.7155963,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,477.0642,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2645",2645,2661,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,899.0825688,"POC","biom","biom","SS",NA,91.74311927,NA,52.9679146,3,0,NA,0,NA,403.6697,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2646",2646,2662,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,1211.009174,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,422.0183,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2647",2647,2663,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,458.7155963,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,440.367,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2648",2648,2664,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,1192.66055,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,422.0183,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2649",2649,2665,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,1669.724771,"POC","biom","biom","SS",NA,201.8348624,NA,116.5294121,3,0,NA,0,NA,422.0183,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2650",2650,2666,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,623.853211,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,50,NA,10.04016064,NA,623.8532,"POC",2,NA,73.39449541,NA,42.37433168,3,0.8,64.87218176,0,0.666666667
"2651",2651,2667,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,917.4311927,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,50,NA,10.04016064,NA,660.5505,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,46.77999554,-4.393001427,2.274871795
"2652",2652,2668,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,1082.568807,"POC","biom","biom","SS",NA,36.69724771,NA,21.18716584,3,50,NA,10.04016064,NA,715.5963,"POC",2,NA,55.04587156,NA,31.78074876,3,0.8,46.77999554,-6.275716324,3.948717949
"2653",2653,2669,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,605.5045872,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,50,NA,10.04016064,NA,605.5046,"POC",2,NA,36.69724771,NA,21.18716584,3,0.8,46.77999554,0,0.666666667
"2654",2654,2670,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,1119.266055,"POC","biom","biom","SS",NA,91.74311927,NA,52.9679146,3,50,NA,10.04016064,NA,844.0367,"POC",2,NA,55.04587156,NA,31.78074876,3,0.8,75.65331423,-2.9104275,1.37254902
"2655",2655,2671,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,1559.633028,"POC","biom","biom","SS",NA,73.39449541,NA,42.37433168,3,50,NA,10.04016064,NA,917.4312,"POC",2,NA,91.74311927,NA,52.9679146,3,0.8,83.07692787,-6.18416546,3.853658537
"2656",2656,2672,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,623.853211,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,642.2018,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2657",2657,2673,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,917.4311927,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,532.1101,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2658",2658,2674,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,1082.568807,"POC","biom","biom","SS",NA,36.69724771,NA,21.18716584,3,0,NA,0,NA,458.7156,"POC",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2659",2659,2675,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",0,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,605.5045872,"POC","biom","biom","SS",NA,55.04587156,NA,31.78074876,3,0,NA,0,NA,587.156,"POC",2,NA,18.34862385,NA,10.59358292,3,0.8,41.02877023,-0.357770876,0.677333333
"2660",2660,2676,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",4,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,1119.266055,"POC","biom","biom","SS",NA,91.74311927,NA,52.9679146,3,0,NA,0,NA,477.0642,"POC",2,NA,0,NA,0,3,0.8,64.87218176,-7.919595949,5.893333333
"2661",2661,2677,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,1559.633028,"POC","biom","biom","SS",NA,73.39449541,NA,42.37433168,3,0,NA,0,NA,495.4128,"POC",2,NA,73.39449541,NA,42.37433168,3,0.8,73.39449541,-11.6,11.88
"2662",2662,2678,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,0.169,"growth rate","biom","biom","dSS",NA,0.016,NA,0.009237604,3,33,NA,9.96978852,NA,0.124,"growth rate",2,NA,0.015,NA,0.008660254,3,0.8,0.015508062,-2.321373169,1.115731116
"2663",2663,2679,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,0.225,"growth rate","biom","biom","dSS",NA,0.008,NA,0.004618802,3,33,NA,9.96978852,NA,0.18,"growth rate",2,NA,0.021,NA,0.012124356,3,0.8,0.015890249,-2.265540392,1.094389439
"2664",2664,2680,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,0.169,"growth rate","biom","biom","dSS",NA,0.016,NA,0.009237604,3,0,NA,0,NA,NA,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2665",2665,2681,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,NA,0.225,"growth rate","biom","biom","dSS",NA,0.008,NA,0.004618802,3,0,NA,0,NA,NA,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2666",2666,2682,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,0.168,"growth rate","biom","biom","dSS",NA,0.021,NA,0.012124356,3,34,NA,9.88372093,NA,0.141,"growth rate",2,NA,0.007,NA,0.004041452,3,0.8,0.015652476,-1.37997338,0.825360544
"2667",2667,2683,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,0.245,"growth rate","biom","biom","dSS",NA,0.005,NA,0.002886751,3,34,NA,9.88372093,NA,0.208,"growth rate",2,NA,0.02,NA,0.011547005,3,0.8,0.01457738,-2.030543248,1.010258824
"2668",2668,2684,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,0.168,"growth rate","biom","biom","dSS",NA,0.021,NA,0.012124356,3,0,NA,0,NA,NA,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2669",2669,2685,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,NA,0.245,"growth rate","biom","biom","dSS",NA,0.005,NA,0.002886751,3,0,NA,0,NA,NA,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2670",2670,2686,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,0.159,"growth rate","biom","biom","dSS",NA,0.01,NA,0.005773503,3,51,NA,9.9609375,NA,0.092,"growth rate",2,NA,0.011,NA,0.006350853,3,0.8,0.010511898,-5.098984017,2.833303167
"2671",2671,2687,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,0.206,"growth rate","biom","biom","dSS",NA,0.021,NA,0.012124356,3,51,NA,9.9609375,NA,0.12,"growth rate",2,NA,0.011,NA,0.006350853,3,0.8,0.016763055,-4.104263906,2.070415184
"2672",2672,2688,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,0.159,"growth rate","biom","biom","dSS",NA,0.01,NA,0.005773503,3,0,NA,0,NA,-0.011,"growth rate",2,NA,0.008,NA,0.004618802,3,0.8,0.009055385,-15.01868755,19.46341463
"2673",2673,2689,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,NA,0.206,"growth rate","biom","biom","dSS",NA,0.021,NA,0.012124356,3,0,NA,0,NA,-0.017,"growth rate",2,NA,0.007,NA,0.004041452,3,0.8,0.015652476,-11.39755792,11.49202721
"2674",2674,2690,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,0.091,"growth rate","biom","biom","dSS",NA,0.008,NA,0.004618802,3,50,NA,10.04016064,NA,0.024,"growth rate",2,NA,0.05,NA,0.028867513,3,0.8,0.035805028,-1.496996473,0.853416537
"2675",2675,2691,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,0.156,"growth rate","biom","biom","dSS",NA,0.01,NA,0.005773503,3,50,NA,10.04016064,NA,0.067,"growth rate",2,NA,0.013,NA,0.007505553,3,0.8,0.011597414,-6.139299937,3.807583643
"2676",2676,2692,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,0.091,"growth rate","biom","biom","dSS",NA,0.008,NA,0.004618802,3,0,NA,0,NA,-0.04,"growth rate",2,NA,0.005,NA,0.002886751,3,0.8,0.006670832,-15.7101842,21.2341573
"2677",2677,2693,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Table 2",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,NA,0.156,"growth rate","biom","biom","dSS",NA,0.01,NA,0.005773503,3,0,NA,0,NA,-0.036,"growth rate",2,NA,0.008,NA,0.004618802,3,0.8,0.009055385,-16.96228241,24.64325203
"2678",2678,2694,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,0.214285714,0.175,"Fv/Fm","productivity","phys","dQ",NA,0.025,NA,0.014433757,3,33,NA,9.96978852,0.214285714,0.2536,"Fv/Fm",1,NA,0.253571429,NA,0.146399533,3,0.8,0.180171404,0.348874138,0.67680943
"2679",2679,2695,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,0.214285714,0.353571429,"Fv/Fm","productivity","phys","dQ",NA,0.014285714,NA,0.008247861,3,33,NA,9.96978852,0.214285714,0.425,"Fv/Fm",1,NA,0.425,NA,0.245373864,3,0.8,0.300690108,0.190039031,0.669676236
"2680",2680,2696,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,0.242857143,0.225,"Fv/Fm","productivity","phys","dQ",NA,0.032142857,NA,0.018557687,3,34,NA,9.88372093,0.242857143,0.2357,"Fv/Fm",1,NA,0.025,NA,0.014433757,3,0.8,0.028793778,0.297683372,0.674051282
"2681",2681,2697,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,0.242857143,0.314285714,"Fv/Fm","productivity","phys","dQ",NA,0.048214286,NA,0.027836531,3,34,NA,9.88372093,0.242857143,0.3893,"Fv/Fm",1,NA,0.014285715,NA,0.008247861,3,0.8,0.035557693,1.687398573,0.903942829
"2682",2682,2698,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,0.292857143,0.196428571,"Fv/Fm","productivity","phys","dQ",NA,0.017857143,NA,0.010309826,3,51,NA,9.9609375,0.292857143,0.2214,"Fv/Fm",1,NA,0.025,NA,0.014433757,3,0.8,0.021724152,0.920634326,0.737297297
"2683",2683,2699,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,0.292857143,0.321428571,"Fv/Fm","productivity","phys","dQ",NA,0.021428571,NA,0.012371791,3,51,NA,9.9609375,0.292857143,0.4,"Fv/Fm",1,NA,0.007142857,NA,0.00412393,3,0.8,0.015971914,3.935479741,1.957333399
"2684",2684,2700,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,0.292857143,0.196428571,"Fv/Fm","productivity","phys","dQ",NA,0.017857143,NA,0.010309826,3,0,NA,0,0.292857143,0.2786,"Fv/Fm",1,NA,0.017857143,NA,0.010309826,3,0.8,0.017857143,3.680000009,1.795200005
"2685",2685,2701,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,0.29285714,0.321428571,"Fv/Fm","productivity","phys","dQ",NA,0.021428571,NA,0.012371791,3,0,NA,0,0.29285714,0.3214,"Fv/Fm",1,NA,0.014285714,NA,0.008247861,3,0.8,0.018210784,0,0.666666667
"2686",2686,2702,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,0.214285714,0.235714286,"Fv/Fm","productivity","phys","dQ",NA,0.014285714,NA,0.008247861,3,50,NA,10.04016064,0.214285714,0.2,"Fv/Fm",1,NA,0.035714286,NA,0.020619653,3,0.8,0.02719919,-1.050451467,0.75862069
"2687",2687,2703,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,0.214285714,0.414285714,"Fv/Fm","productivity","phys","dQ",NA,0.010714286,NA,0.006185896,3,50,NA,10.04016064,0.214285714,0.4036,"Fv/Fm",1,NA,0.025,NA,0.014433757,3,0.8,0.019232732,-0.44566878,0.683218388
"2688",2688,2704,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,0.214285714,0.235714286,"Fv/Fm","productivity","phys","dQ",NA,0.014285714,NA,0.008247861,3,0,NA,0,0.214285714,0.1857,"Fv/Fm",1,NA,0.010714286,NA,0.006185896,3,0.8,0.012626907,-3.16783839,1.502933339
"2689",2689,2705,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,0.214285714,0.414285714,"Fv/Fm","productivity","phys","dQ",NA,0.010714286,NA,0.006185896,3,0,NA,0,0.214285714,0.2571,"Fv/Fm",1,NA,0.007142857,NA,0.00412393,3,0.8,0.009105392,-13.80657573,16.55179445
"2690",2690,2706,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,500.8130081,448.7804878,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,19.51219512,NA,11.26537111,3,33,NA,9.96978852,500.8130081,507.3171,"effective absorption cross section of PS II (?PSII)",1,NA,13.00813008,NA,7.510247403,3,0.8,16.58217728,2.824072348,1.331282052
"2691",2691,2707,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP1",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1104,NA,-1.5,NA,NA,34.43,1.45,20.3,NA,NA,71.7,3,331,NA,100,500.8130081,455.2845528,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,13.00813008,NA,7.510247403,3,33,NA,9.96978852,500.8130081,494.3089,"effective absorption cross section of PS II (?PSII)",1,NA,6.504065041,NA,3.755123702,3,0.8,10.28382979,3.035786558,1.434666669
"2692",2692,2708,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,591.8699187,565.8536585,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,52.03252033,NA,30.04098962,3,34,NA,9.88372093,591.8699187,598.374,"effective absorption cross section of PS II (?PSII)",1,NA,39.02439024,NA,22.53074221,3,0.8,45.99068496,0.565685425,0.693333333
"2693",2693,2709,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP2",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1147,NA,-1.5,NA,NA,34.4,1.61,23.2,NA,NA,70.8,3,344,NA,100,591.8699187,513.8211382,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,32.5203252,NA,18.77561851,3,34,NA,9.88372093,591.8699187,591.8699,"effective absorption cross section of PS II (?PSII)",1,NA,19.51219512,NA,11.26537111,3,0.8,26.81694716,2.328342001,1.118431373
"2694",2694,2710,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,585.3658537,468.2926829,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,26.01626016,NA,15.02049481,3,51,NA,9.9609375,585.3658537,455.2846,"effective absorption cross section of PS II (?PSII)",1,NA,13.00813008,NA,7.510247403,3,0.8,20.56765958,-0.505964426,0.688
"2695",2695,2711,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,585.3658537,422.7642276,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,26.01626016,NA,15.02049481,3,51,NA,9.9609375,585.3658537,500.813,"effective absorption cross section of PS II (?PSII)",1,NA,19.51219512,NA,11.26537111,3,0.8,22.99534248,2.71529004,1.281066667
"2696",2696,2712,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,585.3658537,468.2926829,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,26.01626016,NA,15.02049481,3,0,NA,0,585.3658537,552.8455,"effective absorption cross section of PS II (?PSII)",1,NA,26.01626016,NA,15.02049481,3,0.8,26.01626016,2.600000002,1.230000001
"2697",2697,2713,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP3",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1708,NA,-1.5,NA,NA,34.43,1.53,21.7,NA,NA,70.1,3,512,NA,100,585.3658537,422.7642276,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,26.01626016,NA,15.02049481,3,0,NA,0,585.3658537,533.3333,"effective absorption cross section of PS II (?PSII)",1,NA,13.00813008,NA,7.510247403,3,0.8,20.56765958,4.300697619,2.208000001
"2698",2698,2714,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,695.9349593,682.9268293,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,32.5203252,NA,18.77561851,3,50,NA,10.04016064,695.9349593,676.4228,"effective absorption cross section of PS II (?PSII)",1,NA,45.52845528,NA,26.28586591,3,0.8,39.56268312,-0.131519191,0.668108108
"2699",2699,2715,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,695.9349593,572.3577236,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,26.01626016,NA,15.02049481,3,50,NA,10.04016064,695.9349593,624.3902,"effective absorption cross section of PS II (?PSII)",1,NA,19.51219512,NA,11.26537111,3,0.8,22.99534248,1.810193359,0.939733333
"2700",2700,2716,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","none","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,695.9349593,682.9268293,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,32.5203252,NA,18.77561851,3,0,NA,0,695.9349593,650.4065,"effective absorption cross section of PS II (?PSII)",1,NA,45.52845528,NA,26.28586591,3,0.8,39.56268312,-0.657595949,0.702702703
"2701",2701,2717,"1040","Alderkamp, AC; van Dijken, GL; Lowry, KE; Lewis, KM; Joy-Warren, HL; van de Poll, W; Laan, P; Gerringa, L; Delmont, TO; Jenkins, BD; Arrigo, KR",2019,"Effects of iron and light availability on phytoplankton photosynthetic properties in the Ross Sea","MEPS",1,"EXP4",NA,"Fig. 3",NA,"2014","Lab","seawater",-77.5166646,166.9499962,"Antarctica","total phytoplankton","phytoplankton",6,"microcosm","culture flask",2,NA,"No","Fe","shading",NA,1660,NA,-1.5,NA,NA,43.41,1.06,17.7,NA,NA,57.4,3,498,NA,100,695.9349593,572.3577236,"effective absorption cross section of PS II (?PSII)","productivity","phys","dQ",NA,26.01626016,NA,15.02049481,3,0,NA,0,695.9349593,643.9024,"effective absorption cross section of PS II (?PSII)",1,NA,19.51219512,NA,11.26537111,3,0.8,22.99534248,2.489015868,1.182933333
"2702",2702,2718,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",0,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,4.589582952,"Chla  (mg m-3)","biom","biom","SS",NA,0.819690873,NA,0.579608974,2,NA,NA,NA,NA,4.2624,"Chla  (mg m-3)",1,NA,1.148253155,NA,0.811937593,2,0.571428571,0.997591709,-0.187417307,1.004390656
"2703",2703,2719,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",1,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,4.776156942,"Chla  (mg m-3)","biom","biom","SS",NA,1.148253155,NA,0.811937593,2,NA,NA,NA,NA,4.2857,"Chla  (mg m-3)",1,NA,0.655066764,NA,0.463202151,2,0.571428571,0.934772104,-0.299808846,1.011235668
"2704",2704,2720,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",3,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,3.512666911,"Chla  (mg m-3)","biom","biom","SS",NA,0.655752698,NA,0.46368718,2,NA,NA,NA,NA,4.4956,"Chla  (mg m-3)",1,NA,0.656438632,NA,0.464172208,2,0.571428571,0.656095755,0.856097262,1.091612815
"2705",2705,2721,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",5,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,6.510197549,"Chla  (mg m-3)","biom","biom","SS",NA,1.147567222,NA,0.811452564,2,NA,NA,NA,NA,8.1489,"Chla  (mg m-3)",1,NA,0.819690873,NA,0.579608974,2,0.571428571,0.997196985,0.939029721,1.110222102
"2706",2706,2722,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",7,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,5.573211999,"Chla  (mg m-3)","biom","biom","SS",NA,1.639381745,NA,1.159217949,2,NA,NA,NA,NA,3.4427,"Chla  (mg m-3)",1,NA,0.819004939,NA,0.579123946,2,0.571428571,1.295828228,-0.939502976,1.11033323
"2707",2707,2723,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",0,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,0.702396195,"Chla  (mg m-3)","biom","biom","SS",NA,0.655752698,NA,0.46368718,2,NA,NA,NA,NA,0.8663,"Chla  (mg m-3)",1,NA,0.656438632,NA,0.464172208,2,0.571428571,0.656095755,0.142782446,1.002548353
"2708",2708,2724,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",1,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,9.741631608,"Chla  (mg m-3)","biom","biom","SS",NA,1.311505396,NA,0.927374359,2,NA,NA,NA,NA,10.2341,"Chla  (mg m-3)",1,NA,0.656438632,NA,0.464172208,2,0.571428571,1.037053056,0.271373611,1.009205455
"2709",2709,2725,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",3,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,2.90355771,"Chla  (mg m-3)","biom","biom","SS",NA,0.984314981,NA,0.696015798,2,NA,NA,NA,NA,3.2321,"Chla  (mg m-3)",1,NA,0.818319005,NA,0.578638918,2,0.571428571,0.905130371,0.207428545,1.005378325
"2710",2710,2726,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",5,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,5.408587891,"Chla  (mg m-3)","biom","biom","SS",NA,1.967944028,NA,1.391546567,2,NA,NA,NA,NA,3.6066,"Chla  (mg m-3)",1,NA,1.96657216,NA,1.39057651,2,0.571428571,1.967258214,-0.523411006,1.034244885
"2711",2711,2727,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 4","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",7,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,2.505716115,"Chla  (mg m-3)","biom","biom","SS",NA,3.114825316,NA,2.202514103,2,NA,NA,NA,NA,2.1778,"Chla  (mg m-3)",1,NA,0.983629047,NA,0.695530769,2,0.571428571,2.3097254,-0.081116965,1.000822495
"2712",2712,2728,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 6","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",0,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,1.037037037,"PP","PP","phys","dQ",NA,0.185185185,NA,0.1309457,2,NA,NA,NA,NA,1.0741,"PP",1,NA,0.111111111,NA,0.07856742,2,0.571428571,0.152707616,0.138591786,1.00240096
"2713",2713,2729,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 6","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",3,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,2.37037037,"PP","PP","phys","dQ",NA,0.555555556,NA,0.392837101,2,NA,NA,NA,NA,2.5556,"PP",1,NA,1.185185185,NA,0.838052481,2,0.571428571,0.925555481,0.114331456,1.00163396
"2714",2714,2730,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 1",NA,"Fig. 6","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",7,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,3.074074074,"PP","PP","phys","dQ",NA,0.740740741,NA,0.523782801,2,NA,NA,NA,NA,1.9259,"PP",1,NA,0.481481481,NA,0.340458821,2,0.571428571,0.624708437,-1.050225381,1.137871669
"2715",2715,2731,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 6","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",0,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,0.851851852,"PP","PP","phys","dQ",NA,0.148148148,NA,0.10475656,2,NA,NA,NA,NA,0.8889,"PP",1,NA,0.074074074,NA,0.05237828,2,0.571428571,0.117121395,0.180701581,1.004081633
"2716",2716,2732,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 6","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",3,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,1.148148148,"PP","PP","phys","dQ",NA,1.481481481,NA,1.047565602,2,NA,NA,NA,NA,1.2963,"PP",1,NA,1.37037037,NA,0.968998182,2,0.571428571,1.427007767,0.059324193,1.00043992
"2717",2717,2733,"1056","Liao, JZ; Xu, J; Yuan, XC; Liang, YX; Guo, YJ; Zhou, WH; Huang, H; Liu, S; Long, AM",2019,"Interactive Effects of Ultraviolet Radiation and Dissolved Organic Carbon on Phytoplankton Growth and Photosynthesis in Sanya Bay, Northern South China Sea","Ocean Science",1,"station 2",NA,"Fig. 6","summer","2016","Lab","estuary",18.24306,109.505,"Sanya Bay","total phytoplankton","phytoplankton",7,"microcosm","culture flask",25,NA,"No","none","light reduced",NA,NA,NA,26,8,NA,NA,0.25,3.49,NA,NA,10.17,2,30,NA,100,NA,1.481481481,"PP","PP","phys","dQ",NA,0.407407407,NA,0.28808054,2,NA,NA,NA,NA,1.2222,"PP",1,NA,0.259259259,NA,0.18332398,2,0.571428571,0.34146461,-0.433860916,1.023529412
"2718",2718,2734,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2719",2719,2735,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2720",2720,2736,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,5294.1176,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2721",2721,2737,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,1218,NA,90.89552239,NA,11911.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2722",2722,2738,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,1218,NA,90.89552239,NA,19852.9412,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,3150.630189,-0.224044813,0.670849673
"2723",2723,2739,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,1218,NA,90.89552239,NA,24264.7059,"cells ml-1",2,NA,6113.120497,NA,3529.411765,3,0.8,4616.569751,-1.605470101,0.881461187
"2724",2724,2740,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,1218,NA,90.89552239,NA,39264.7059,"cells ml-1",2,NA,1528.280124,NA,882.3529412,3,0.8,1948.182544,0.362328651,0.677606838
"2725",2725,2741,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,1218,NA,90.89552239,NA,32647.0588,"cells ml-1",2,NA,12226.24099,NA,7058.823529,3,0.8,8795.912664,-1.324144437,0.812779874
"2726",2726,2742,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2727",2727,2743,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2728",2728,2744,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,4411.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2729",2729,2745,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,534,NA,39.85074627,NA,9705.8824,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,2701.643099,-0.130639453,0.668088889
"2730",2730,2746,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,534,NA,39.85074627,NA,17205.8824,"cells ml-1",2,NA,764.1400622,NA,441.1764706,3,0.8,2755.146176,-1.024820184,0.754188034
"2731",2731,2747,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,534,NA,39.85074627,NA,23382.3529,"cells ml-1",2,NA,4584.840373,NA,2647.058824,3,0.8,3624.634572,-2.23957668,1.084641975
"2732",2732,2748,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,534,NA,39.85074627,NA,26029.4118,"cells ml-1",2,NA,6877.260559,NA,3970.588235,3,0.8,5126.00737,-1.927885043,0.976395062
"2733",2733,2749,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,534,NA,39.85074627,NA,32205.8824,"cells ml-1",2,NA,11462.10093,NA,6617.647059,3,0.8,8265.438527,-1.451828594,0.842317189
"2734",2734,2750,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2735",2735,2751,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2736",2736,2752,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,4411.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2737",2737,2753,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,289,NA,21.56716418,NA,10147.0588,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,2701.643099,0,0.666666667
"2738",2738,2754,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,289,NA,21.56716418,NA,20294.1176,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,3150.630189,-0.112022407,0.667712418
"2739",2739,2755,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,289,NA,21.56716418,NA,31764.7059,"cells ml-1",2,NA,9933.820808,NA,5735.294118,3,0.8,7208.882929,-0.19583682,0.669862672
"2740",2740,2756,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,289,NA,21.56716418,NA,33088.2353,"cells ml-1",2,NA,1528.280124,NA,882.3529412,3,0.8,1948.182544,-2.173971906,1.060512821
"2741",2741,2757,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,289,NA,21.56716418,NA,39264.7059,"cells ml-1",2,NA,764.1400622,NA,441.1764706,3,0.8,1708.669123,-3.718064012,1.818666667
"2742",2742,2758,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2743",2743,2759,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,0,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2744",2744,2760,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2745",2745,2761,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,125,NA,9.328358209,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2746",2746,2762,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,125,NA,9.328358209,NA,3088.2353,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2747",2747,2763,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,125,NA,9.328358209,NA,7058.8235,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2748",2748,2764,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,125,NA,9.328358209,NA,13676.4706,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,2292.420186,-8.62176402,6.861234568
"2749",2749,2765,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,125,NA,9.328358209,NA,22058.8235,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2750",2750,2766,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,0,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2751",2751,2767,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2752",2752,2768,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2753",2753,2769,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,78,NA,5.820895522,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2754",2754,2770,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,78,NA,5.820895522,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2755",2755,2771,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,78,NA,5.820895522,NA,2647.0588,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2756",2756,2772,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,78,NA,5.820895522,NA,3970.5882,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2757",2757,2773,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,78,NA,5.820895522,NA,8382.3529,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,2292.420186,-13.54848632,15.96345679
"2758",2758,2774,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2759",2759,2775,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2760",2760,2776,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2761",2761,2777,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2762",2762,2778,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2763",2763,2779,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2764",2764,2780,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2765",2765,2781,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2766",2766,2782,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2767",2767,2783,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2768",2768,2784,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2769",2769,2785,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2770",2770,2786,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2771",2771,2787,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2772",2772,2788,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2773",2773,2789,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2774",2774,2790,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,441.1764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2775",2775,2791,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2776",2776,2792,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,4411.764706,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2777",2777,2793,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,10147.05882,"cells ml-1","abundance","biom","SS",NA,3056.560249,NA,1764.705882,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2778",2778,2794,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,20735.29412,"cells ml-1","abundance","biom","SS",NA,3820.700311,NA,2205.882353,3,10,NA,0.746268657,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2779",2779,2795,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,33529.41176,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2780",2780,2796,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,38382.35294,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2781",2781,2797,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 2",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,47205.88235,"cells ml-1","abundance","biom","SS",NA,2292.420186,NA,1323.529412,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2782",2782,2798,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2783",2783,2799,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,3088.2353,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2784",2784,2800,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,8823.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2785",2785,2801,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,19852.9412,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2786",2786,2802,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,1218,NA,90.89552239,NA,32205.8824,"cells ml-1",2,NA,5348.980435,NA,3088.235294,3,0.8,5348.980435,0.065982888,0.667029478
"2787",2787,2803,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,1218,NA,90.89552239,NA,41029.4118,"cells ml-1",2,NA,9169.680746,NA,5294.117647,3,0.8,9169.680746,0.115470054,0.667777778
"2788",2788,2804,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,1218,NA,90.89552239,NA,47205.8824,"cells ml-1",2,NA,9169.680746,NA,5294.117647,3,0.8,9169.680746,0.538860251,0.690864198
"2789",2789,2805,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,1218,NA,90.89552239,NA,45882.3529,"cells ml-1",2,NA,13754.52112,NA,7941.176471,3,0.8,13754.52112,0.205280096,0.670178326
"2790",2790,2806,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2791",2791,2807,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,1764.7059,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2792",2792,2808,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,4411.7647,"cells ml-1",2,NA,3056.560249,NA,1764.705882,3,0.8,NA,NA,NA
"2793",2793,2809,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,13235.2941,"cells ml-1",2,NA,3820.700311,NA,2205.882353,3,0.8,NA,NA,NA
"2794",2794,2810,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,534,NA,39.85074627,NA,18529.4118,"cells ml-1",2,NA,10697.96087,NA,6176.470588,3,0.8,8457.480667,-1.251937274,0.797278912
"2795",2795,2811,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,534,NA,39.85074627,NA,25588.2353,"cells ml-1",2,NA,10697.96087,NA,6176.470588,3,0.8,9963.167462,-1.133587053,0.773751634
"2796",2796,2812,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,534,NA,39.85074627,NA,22500,"cells ml-1",2,NA,10697.96087,NA,6176.470588,3,0.8,9963.167462,-1.487833008,0.851137255
"2797",2797,2813,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,534,NA,39.85074627,NA,32647.0588,"cells ml-1",2,NA,12226.24099,NA,7058.823529,3,0.8,13012.83636,-0.596695883,0.696337165
"2798",2798,2814,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2799",2799,2815,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,1764.7059,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2800",2800,2816,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,3970.5882,"cells ml-1",2,NA,1528.280124,NA,882.3529412,3,0.8,NA,NA,NA
"2801",2801,2817,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,16323.5294,"cells ml-1",2,NA,4584.840373,NA,2647.058824,3,0.8,NA,NA,NA
"2802",2802,2818,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,289,NA,21.56716418,NA,24264.7059,"cells ml-1",2,NA,8405.540684,NA,4852.941176,3,0.8,7045.023275,-0.851665036,0.727111111
"2803",2803,2819,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,289,NA,21.56716418,NA,33970.5882,"cells ml-1",2,NA,11462.10093,NA,6617.647059,3,0.8,10379.37384,-0.442053188,0.682950918
"2804",2804,2820,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,289,NA,21.56716418,NA,40147.0588,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,6683.495915,-0.105615738,0.667596224
"2805",2805,2821,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,289,NA,21.56716418,NA,42352.9412,"cells ml-1",2,NA,14518.66118,NA,8382.352941,3,0.8,14141.75332,0,0.666666667
"2806",2806,2822,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2807",2807,2823,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2808",2808,2824,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,3088.2353,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2809",2809,2825,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,9264.7059,"cells ml-1",2,NA,1528.280124,NA,882.3529412,3,0.8,NA,NA,NA
"2810",2810,2826,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,125,NA,9.328358209,NA,14117.6471,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,4115.02017,-3.430760111,1.647509579
"2811",2811,2827,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,125,NA,9.328358209,NA,20294.1176,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,6683.495915,-2.323546234,1.116572259
"2812",2812,2828,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,125,NA,9.328358209,NA,28676.4706,"cells ml-1",2,NA,11462.10093,NA,6617.647059,3,0.8,10379.37384,-0.952114558,0.742210178
"2813",2813,2829,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,125,NA,9.328358209,NA,34411.7647,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,9860.072046,-0.644309813,0.701261261
"2814",2814,2830,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2815",2815,2831,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2816",2816,2832,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,1764.7059,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2817",2817,2833,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,4411.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2818",2818,2834,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,78,NA,5.820895522,NA,6176.4706,"cells ml-1",2,NA,2292.420186,NA,1323.529412,3,0.8,4115.02017,-4.974602162,2.728888889
"2819",2819,2835,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,78,NA,5.820895522,NA,11470.5882,"cells ml-1",2,NA,4584.840373,NA,2647.058824,3,0.8,7249.269143,-3.115932772,1.475753086
"2820",2820,2836,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,78,NA,5.820895522,NA,24264.7059,"cells ml-1",2,NA,5348.980435,NA,3088.235294,3,0.8,7506.485086,-1.786690382,0.932688543
"2821",2821,2837,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,78,NA,5.820895522,NA,30882.3529,"cells ml-1",2,NA,13754.52112,NA,7941.176471,3,0.8,13754.52112,-0.667160311,0.703758573
"2822",2822,2838,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2823",2823,2839,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2824",2824,2840,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2825",2825,2841,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2826",2826,2842,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,43,NA,3.208955224,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2827",2827,2843,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,43,NA,3.208955224,NA,1764.7059,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2828",2828,2844,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,43,NA,3.208955224,NA,3088.2353,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2829",2829,2845,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,43,NA,3.208955224,NA,4411.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2830",2830,2846,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2831",2831,2847,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2832",2832,2848,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,441.1765,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2833",2833,2849,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2834",2834,2850,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,17,NA,1.268656716,NA,1323.5294,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2835",2835,2851,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,17,NA,1.268656716,NA,1764.7059,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2836",2836,2852,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,17,NA,1.268656716,NA,3088.2353,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2837",2837,2853,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,17,NA,1.268656716,NA,4411.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2838",2838,2854,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,1323.529412,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2839",2839,2855,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3970.588235,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2840",2840,2856,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,9705.882353,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2841",2841,2857,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23823.52941,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2842",2842,2858,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31764.70588,"cells ml-1","abundance","biom","SS",NA,5348.980435,NA,3088.235294,3,10,NA,0.746268657,NA,882.3529,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2843",2843,2859,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,39705.88235,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,10,NA,0.746268657,NA,2205.8824,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2844",2844,2860,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,41029.41176,"cells ml-1","abundance","biom","SS",NA,9169.680746,NA,5294.117647,3,10,NA,0.746268657,NA,3088.2353,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2845",2845,2861,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,42352.94118,"cells ml-1","abundance","biom","SS",NA,13754.52112,NA,7941.176471,3,10,NA,0.746268657,NA,4411.7647,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2846",2846,2862,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2847",2847,2863,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2848",2848,2864,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,3861.3861,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2849",2849,2865,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,1218,NA,90.89552239,NA,13217.8218,"cells ml-1",2,NA,3086.823221,NA,1782.178218,3,0.8,NA,NA,NA
"2850",2850,2866,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,1218,NA,90.89552239,NA,22574.2574,"cells ml-1",2,NA,5401.940637,NA,3118.811881,3,0.8,5401.940637,-0.131965776,0.668117914
"2851",2851,2867,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,1218,NA,90.89552239,NA,33712.8713,"cells ml-1",2,NA,9260.469664,NA,5346.534653,3,0.8,6902.346558,0.722956891,0.710222222
"2852",2852,2868,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,1218,NA,90.89552239,NA,47970.297,"cells ml-1",2,NA,3858.529027,NA,2227.722772,3,0.8,4694.103157,2.581709748,1.222102102
"2853",2853,2869,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,1218,NA,90.89552239,NA,54207.9208,"cells ml-1",2,NA,10803.88127,NA,6237.623762,3,0.8,7945.19755,2.243088616,1.085953878
"2854",2854,2870,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2855",2855,2871,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2856",2856,2872,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,2970.297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2857",2857,2873,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,534,NA,39.85074627,NA,13217.8218,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2858",2858,2874,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,534,NA,39.85074627,NA,23910.8911,"cells ml-1",2,NA,3858.529027,NA,2227.722772,3,0.8,4694.103157,0.07593264,0.667147147
"2859",2859,2875,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,534,NA,39.85074627,NA,31485.1485,"cells ml-1",2,NA,6173.646443,NA,3564.356436,3,0.8,4880.696057,0.657267069,0.702666667
"2860",2860,2876,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,534,NA,39.85074627,NA,40396.0396,"cells ml-1",2,NA,3858.529027,NA,2227.722772,3,0.8,4694.103157,1.290854874,0.805525526
"2861",2861,2877,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,534,NA,39.85074627,NA,41732.6733,"cells ml-1",2,NA,7717.058054,NA,4455.445545,3,0.8,5877.136318,1.334252557,0.815019157
"2862",2862,2878,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2863",2863,2879,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2864",2864,2880,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,3415.8416,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2865",2865,2881,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,289,NA,21.56716418,NA,12326.7327,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2866",2866,2882,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,289,NA,21.56716418,NA,24801.9802,"cells ml-1",2,NA,2315.117416,NA,1336.633663,3,0.8,4155.762944,0.257307008,0.672183908
"2867",2867,2883,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,289,NA,21.56716418,NA,34603.9604,"cells ml-1",2,NA,7717.058054,NA,4455.445545,3,0.8,5877.136318,0.970365496,0.7451341
"2868",2868,2884,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,289,NA,21.56716418,NA,43069.3069,"cells ml-1",2,NA,3086.823221,NA,1782.178218,3,0.8,4399.399973,1.863440435,0.956034188
"2869",2869,2885,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,289,NA,21.56716418,NA,48415.8416,"cells ml-1",2,NA,2315.117416,NA,1336.633663,3,0.8,2728.39204,4.833659759,2.613688889
"2870",2870,2886,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2871",2871,2887,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2872",2872,2888,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2873",2873,2889,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,125,NA,9.328358209,NA,3415.8416,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2874",2874,2890,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,125,NA,9.328358209,NA,7425.7426,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2875",2875,2891,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,125,NA,9.328358209,NA,13663.3663,"cells ml-1",2,NA,1543.411611,NA,891.0891089,3,0.8,2440.348028,-4.527839809,2.375111111
"2876",2876,2892,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,125,NA,9.328358209,NA,27475.2475,"cells ml-1",2,NA,4630.234832,NA,2673.267327,3,0.8,5030.906342,-0.85019029,0.726901961
"2877",2877,2893,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,125,NA,9.328358209,NA,36831.6832,"cells ml-1",2,NA,4630.234832,NA,2673.267327,3,0.8,3934.94296,0.99640379,0.749401709
"2878",2878,2894,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2879",2879,2895,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,0,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2880",2880,2896,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2881",2881,2897,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,78,NA,5.820895522,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2882",2882,2898,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,78,NA,5.820895522,NA,2079.2079,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2883",2883,2899,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,78,NA,5.820895522,NA,2970.297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2884",2884,2900,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,78,NA,5.820895522,NA,8316.8317,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2885",2885,2901,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,78,NA,5.820895522,NA,6980.198,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2886",2886,2902,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2887",2887,2903,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2888",2888,2904,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2889",2889,2905,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,43,NA,3.208955224,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2890",2890,2906,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,43,NA,3.208955224,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2891",2891,2907,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,43,NA,3.208955224,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2892",2892,2908,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,43,NA,3.208955224,NA,1188.1188,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2893",2893,2909,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,43,NA,3.208955224,NA,742.5743,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2894",2894,2910,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2895",2895,2911,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2896",2896,2912,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2897",2897,2913,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,17,NA,1.268656716,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2898",2898,2914,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,17,NA,1.268656716,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2899",2899,2915,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,17,NA,1.268656716,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2900",2900,2916,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,17,NA,1.268656716,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2901",2901,2917,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,17,NA,1.268656716,NA,742.5743,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2902",2902,2918,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,148.5149,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2903",2903,2919,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,742.5742574,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2904",2904,2920,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,3415.841584,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2905",2905,2921,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,11435.64356,"cells ml-1","abundance","biom","SS",NA,NA,NA,NA,3,10,NA,0.746268657,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2906",2906,2922,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,23465.34653,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,10,NA,0.746268657,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2907",2907,2923,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,27475.24752,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,10,NA,0.746268657,NA,297.0297,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2908",2908,2924,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,32821.78218,"cells ml-1","abundance","biom","SS",NA,5401.940637,NA,3118.811881,3,10,NA,0.746268657,NA,742.5743,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2909",2909,2925,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,31930.69307,"cells ml-1","abundance","biom","SS",NA,3086.823221,NA,1782.178218,3,10,NA,0.746268657,NA,742.5743,"cells ml-1",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2910",2910,2926,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.034641016,NA,0.04,3,1218,NA,90.96340553,NA,0.52,"specific growth rate (d-1)",2,NA,0.034641016,NA,0.02,3,0.8,0.034641016,0.692820323,0.706666667
"2911",2911,2927,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.034641016,NA,0.04,3,534,NA,39.88050784,NA,0.52,"specific growth rate (d-1)",2,NA,0.034641016,NA,0.02,3,0.8,0.034641016,0.692820323,0.706666667
"2912",2912,2928,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.04,3,289,NA,21.5832711,NA,0.53,"specific growth rate (d-1)",2,NA,0.017320508,NA,0.01,3,0.8,0.017320508,1.847520861,0.951111111
"2913",2913,2929,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.08660254,NA,0.04,3,125,NA,9.335324869,NA,0.36,"specific growth rate (d-1)",2,NA,0.08660254,NA,0.05,3,0.8,0.08660254,-1.20088856,0.786844444
"2914",2914,2930,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.051961524,NA,0.04,3,78,NA,5.825242718,NA,0.24,"specific growth rate (d-1)",2,NA,0.051961524,NA,0.03,3,0.8,0.051961524,-3.849001795,1.901234568
"2915",2915,2931,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,43,NA,3.211351755,NA,0.14,"specific growth rate (d-1)",2,NA,0.069282032,NA,0.04,3,0.8,0.069282032,-4.041451884,2.027777778
"2916",2916,2932,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.173205081,NA,0.04,3,17,NA,1.269604182,NA,-0.23,"specific growth rate (d-1)",2,NA,0.173205081,NA,0.1,3,0.8,0.173205081,NA,NA
"2917",2917,2933,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1339,NA,100,NA,0.49,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,10,NA,0.74682599,NA,0.21,"specific growth rate (d-1)",2,NA,0.069282032,NA,0.04,3,0.8,0.069282032,-3.233161507,1.537777778
"2918",2918,2934,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,1218,NA,90.89552239,NA,0.45,"specific growth rate (d-1)",2,NA,0.155884573,NA,0.09,3,0.8,0.110905365,-0.360667854,0.677506775
"2919",2919,2935,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,534,NA,39.85074627,NA,0.42,"specific growth rate (d-1)",2,NA,0.138564065,NA,0.08,3,0.8,0.098742088,-0.648153195,0.701675214
"2920",2920,2936,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,289,NA,21.56716418,NA,0.48,"specific growth rate (d-1)",2,NA,0.034641016,NA,0.02,3,0.8,0.027386128,-0.584237395,0.695111111
"2921",2921,2937,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,125,NA,9.328358209,NA,0.37,"specific growth rate (d-1)",2,NA,0.051961524,NA,0.03,3,0.8,0.038729833,-2.685268453,1.267555556
"2922",2922,2938,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,78,NA,5.820895522,NA,0.33,"specific growth rate (d-1)",2,NA,0.017320508,NA,0.01,3,0.8,0.017320508,-7.851963661,5.804444444
"2923",2923,2939,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,43,NA,3.208955224,NA,0.22,"specific growth rate (d-1)",2,NA,0.051961524,NA,0.03,3,0.8,0.038729833,-5.78365513,3.454222222
"2924",2924,2940,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,17,NA,1.268656716,NA,-0.4,"specific growth rate (d-1)",2,NA,0.138564065,NA,0.08,3,0.8,0.098742088,NA,NA
"2925",2925,2941,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.5,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,10,NA,0.746268657,NA,-0.46,"specific growth rate (d-1)",2,NA,0.069282032,NA,0.04,3,0.8,0.050497525,NA,NA
"2926",2926,2942,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",4,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,1218,NA,90.89552239,NA,0.48,"specific growth rate (d-1)",2,NA,0.051961524,NA,0.03,3,0.8,0.061237244,0.130639453,0.668088889
"2927",2927,2943,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",6,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,534,NA,39.85074627,NA,0.49,"specific growth rate (d-1)",2,NA,0.121243557,NA,0.07,3,0.8,0.098742088,0.162038299,0.668854701
"2928",2928,2944,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",8,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,289,NA,21.56716418,NA,0.47,"specific growth rate (d-1)",2,NA,0.034641016,NA,0.02,3,0.8,0.054772256,0,0.666666667
"2929",2929,2945,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",11,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,125,NA,9.328358209,NA,0.36,"specific growth rate (d-1)",2,NA,0.08660254,NA,0.05,3,0.8,0.078421936,-1.122135015,0.771598916
"2930",2930,2946,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",13,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,78,NA,5.820895522,NA,0.3,"specific growth rate (d-1)",2,NA,0.155884573,NA,0.09,3,0.8,0.120623381,-1.127476274,0.772600229
"2931",2931,2947,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",15,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,43,NA,3.208955224,NA,0.11,"specific growth rate (d-1)",2,NA,0.034641016,NA,0.02,3,0.8,0.054772256,-5.258136552,2.970666667
"2932",2932,2948,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",18,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,17,NA,1.268656716,NA,-0.06,"specific growth rate (d-1)",2,NA,0.069282032,NA,0.04,3,0.8,0.069282032,NA,NA
"2933",2933,2949,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Table 1",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",20,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1340,NA,100,NA,0.47,"specific growth rate (d-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,10,NA,0.746268657,NA,-0.25,"specific growth rate (d-1)",2,NA,0.08660254,NA,0.05,3,0.8,0.078421936,NA,NA
"2934",2934,2950,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.497101449,"Fv/Fm","productivity","phys","dQ",NA,0.025102186,NA,0.014492754,3,250,NA,16.66666667,NA,0.6217,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.019117255,5.215714472,2.933639788
"2935",2935,2951,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.514492754,"Fv/Fm","productivity","phys","dQ",NA,0.025102186,NA,0.014492754,3,250,NA,16.66666667,NA,0.6246,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.019117255,4.609236028,2.437088064
"2936",2936,2952,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",27.2668,-82.6923,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.5,"Fv/Fm","productivity","phys","dQ",NA,0.020081749,NA,0.011594203,3,250,NA,16.66666667,NA,0.6217,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.015876016,6.134492674,3.802666698
"2937",2937,2953,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.436231884,"Fv/Fm","productivity","phys","dQ",NA,0.015061311,NA,0.008695652,3,250,NA,16.66666667,NA,0.5725,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.012799653,8.514723614,6.708376519
"2938",2938,2954,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.465217391,"Fv/Fm","productivity","phys","dQ",NA,0.015061311,NA,0.008695652,3,250,NA,16.66666667,NA,0.5841,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.012799653,7.427737642,5.264273873
"2939",2939,2955,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",26.8871,-82.4406,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.436231884,"Fv/Fm","productivity","phys","dQ",NA,0.040163497,NA,0.023188406,3,250,NA,16.66666667,NA,0.5841,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.029273927,4.039801962,2.026666657
"2940",2940,2956,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.517391304,"Fv/Fm","productivity","phys","dQ",NA,0.015061311,NA,0.008695652,3,250,NA,16.66666667,NA,0.6362,"Fv/Fm",1,NA,0.015061311,NA,0.008695652,3,0.8,0.015061311,6.312363085,3.987160643
"2941",2941,2957,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.537681159,"Fv/Fm","productivity","phys","dQ",NA,0.015061311,NA,0.008695652,3,250,NA,16.66666667,NA,0.6362,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.012799653,6.159587321,3.82837633
"2942",2942,2958,"1058","Tilney, CL; Shankar, S; Hubbard, KA; Corcoran, AA",2019,"Is Karenia brevis really a low-light-adapted species?","HARMFUL ALGAE",1,"10–1500??mol photons, response growth rates",NA,"Fig. 6",NA,NA,"Lab","coastal",27.2668,-82.6318,"bay","Karenia brevis","phytoplankton",7,"microcosm","culture flask",0.08,NA,"No","none","light gradient","12",NA,NA,22.5,NA,NA,NA,NA,NA,NA,NA,NA,0,1500,NA,100,NA,0.526086957,"Fv/Fm","productivity","phys","dQ",NA,0.010040873,NA,0.005797101,3,250,NA,16.66666667,NA,0.6246,"Fv/Fm",1,NA,0.010040873,NA,0.005797101,3,0.8,0.010040873,7.851964219,5.804445174
"2943",2943,2959,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Table 1","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.28,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,5.5,NA,2.75,NA,0.13,"growth rate d-1",2,NA,0.01,NA,0.005773503,3,0.8,0.01,-12,12.66666667
"2944",2944,2960,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Table 1","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,5.5,NA,2.75,NA,0.12,"growth rate d-1",2,NA,0.002,NA,0.001154701,3,0.8,0.007211103,-16.64100589,23.74358974
"2945",2945,2961,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Table 1","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,5.5,NA,2.75,NA,0.12,"growth rate d-1",2,NA,0.01,NA,0.005773503,3,0.8,0.01,-12,12.66666667
"2946",2946,2962,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Table 1","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,241.8,"cell volume (µm^3)","biom","biom","dSS",NA,14.46,NA,8.348484892,3,5.5,NA,2.75,NA,189,"cell volume (µm^3)",2,NA,14.26,NA,8.233014839,3,0.8,14.36034819,-2.941432858,1.387668938
"2947",2947,2963,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Table 1","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,208.61,"cell volume (µm^3)","biom","biom","dSS",NA,15.23,NA,8.7930446,3,5.5,NA,2.75,NA,171.43,"cell volume (µm^3)",2,NA,6.03,NA,3.481422123,3,0.8,11.58261197,-2.567987262,1.216213215
"2948",2948,2964,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Table 1","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,207.19,"cell volume (µm^3)","biom","biom","dSS",NA,14.22,NA,8.209920828,3,5.5,NA,2.75,NA,179.93,"cell volume (µm^3)",2,NA,7.21,NA,4.162695441,3,0.8,11.27369726,-1.934414193,0.978496523
"2949",2949,2965,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 1 S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,2.5,NA,1.25,NA,0.092,"growth rate d-1",2,NA,0.007922506,NA,0.004574061,3,0.8,0.009021255,-15.78261121,21.42423473
"2950",2950,2966,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 1 S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,6.5,NA,3.25,NA,0.1356,"growth rate d-1",2,NA,0.006930732,NA,0.00400146,3,0.8,0.008603344,-12.50017688,13.68786851
"2951",2951,2967,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 1 S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,5,NA,2.5,NA,0.2118,"growth rate d-1",2,NA,0.011882924,NA,0.006860609,3,0.8,0.010981891,-4.242099017,2.166283673
"2952",2952,2968,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 1 S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,30,NA,15,NA,0.2048,"growth rate d-1",2,NA,0.006932401,NA,0.004002424,3,0.8,0.008604016,-6.065883994,3.732912386
"2953",2953,2969,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 1 S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,40,NA,20,NA,0.2255,"growth rate d-1",2,NA,0.017823551,NA,0.010290432,3,0.8,0.01445128,-2.463168975,1.172266783
"2954",2954,2970,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 1 S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.27,"growth rate d-1","biom","biom","dSS",NA,0.01,NA,0.005773503,3,90,NA,45,NA,0.2599,"growth rate d-1",2,NA,0.004948853,NA,0.002857222,3,0.8,0.007889586,-1.022617975,0.753812294
"2955",2955,2971,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 5S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.582524272,"Q Chla (pg Chl a cell -1)","cellular content","phys","Q",NA,NA,NA,NA,3,5.5,NA,2.75,NA,3.8592,"Q Chla (pg Chl a cell -1)",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2956",2956,2972,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 5S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.582524272,"Q Chla (pg Chl a cell -1)","cellular content","phys","Q",NA,NA,NA,NA,3,5.5,NA,2.75,NA,3.665,"Q Chla (pg Chl a cell -1)",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2957",2957,2973,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 5S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.461165049,"Q Chla (pg Chl a cell -1)","cellular content","phys","Q",NA,NA,NA,NA,3,5.5,NA,2.75,NA,3.4223,"Q Chla (pg Chl a cell -1)",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2958",2958,2974,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 5S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,3.719457014,"Q C (pmol C cell -1)","biom","biom","dSS",NA,NA,NA,NA,3,5.5,NA,2.75,NA,4.2624,"Q C (pmol C cell -1)",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2959",2959,2975,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 5S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,3.42081448,"Q C (pmol C cell -1)","biom","biom","dSS",NA,NA,NA,NA,3,5.5,NA,2.75,NA,4.0181,"Q C (pmol C cell -1)",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2960",2960,2976,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 5S","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,2.850678733,"Q C (pmol C cell -1)","biom","biom","dSS",NA,NA,NA,NA,3,5.5,NA,2.75,NA,3.9367,"Q C (pmol C cell -1)",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2961",2961,2977,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 2A","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.549714286,"Fv/Fm","productivity","phys","dQ",NA,NA,NA,NA,3,5.5,NA,2.75,NA,0.7571,"Fv/Fm",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2962",2962,2978,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 2A","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.589142857,"Fv/Fm","productivity","phys","dQ",NA,NA,NA,NA,3,5.5,NA,2.75,NA,0.7829,"Fv/Fm",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2963",2963,2979,"1068","Schiffrine, N; Tremblay, JE; Babin, M",2020,"Growth and Elemental Stoichiometry of the Ecologically-Relevant Arctic Diatom Chaetoceros gelidus: A Mix of Polar and Temperate","FRONTIERS IN MARINE SCIENCE",1,"sub-saturating (LL; 5.5 ?mol photons m?2 s?1) or saturating irradiance (HL; 200 ?mol photons m?2 s?1)",NA,"Fig. 2A","summer",NA,"Lab","culture",NA,NA,NA,"Cheatocerus gelidus","phytoplankton",10,"microcosm","culture flask",0.5,NA,"No","nut","light reduced","12",NA,NA,0,NA,NA,NA,11.11,100,NA,NA,100,3,200,NA,100,NA,0.570285714,"Fv/Fm","productivity","phys","dQ",NA,NA,NA,NA,3,5.5,NA,2.75,NA,0.7469,"Fv/Fm",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"2964",2964,2980,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",0,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.2365895,NA,100,NA,4.826530612,"Chl a (µg L-1)","biom","biom","SS",NA,0.309294787,NA,0.178571429,3,32.89256198,NA,64.19740718,NA,4.648,"Chl a (µg L-1)",2,NA,0.220924848,NA,0.12755102,3,0.8,0.268766677,-0.531528478,0.69021021
"2965",2965,2981,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",4,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.2365895,NA,100,NA,2.964285714,"Chl a (µg L-1)","biom","biom","SS",NA,0.353479757,NA,0.204081633,3,32.89256198,NA,64.19740718,NA,2.2755,"Chl a (µg L-1)",2,NA,0.220924848,NA,0.12755102,3,0.8,0.29475051,-1.869446833,0.957902622
"2966",2966,2982,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",7,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,50.86699861,NA,100,NA,3.346938776,"Chl a (µg L-1)","biom","biom","SS",NA,0.265109817,NA,0.153061224,3,29.54776449,NA,58.08827982,NA,2.2755,"Chl a (µg L-1)",2,NA,0.353479757,NA,0.204081633,3,0.8,0.312434916,-2.743428512,1.293866667
"2967",2967,2983,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",10,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,50.86699861,NA,100,NA,2.556122449,"Chl a (µg L-1)","biom","biom","SS",NA,0.265109817,NA,0.153061224,3,29.54776449,NA,58.08827982,NA,1.8418,"Chl a (µg L-1)",2,NA,0.176739878,NA,0.102040816,3,0.8,0.225300022,-2.536300556,1.202735043
"2968",2968,2984,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",14,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,1.382653061,"Chl a (µg L-1)","biom","biom","SS",NA,0.309294787,NA,0.178571429,3,24.70920384,NA,46.64160304,NA,1.6378,"Chl a (µg L-1)",2,NA,0.176739878,NA,0.102040816,3,0.8,0.251893082,0.810191494,0.721367521
"2969",2969,2985,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",17,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,1.280612245,"Chl a (µg L-1)","biom","biom","SS",NA,0.309294787,NA,0.178571429,3,24.70920384,NA,46.64160304,NA,1.7143,"Chl a (µg L-1)",2,NA,0.353479757,NA,0.204081633,3,0.8,0.332122872,1.044609707,0.757600787
"2970",2970,2986,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",21,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,59.05035676,NA,100,NA,1.433673469,"Chl a (µg L-1)","biom","biom","SS",NA,0.220924848,NA,0.12755102,3,19.88296289,NA,33.67119858,NA,2.1735,"Chl a (µg L-1)",2,NA,0.265109817,NA,0.153061224,3,0.8,0.24401947,2.425366853,1.156867031
"2971",2971,2987,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",24,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,59.05035676,NA,100,NA,1.025510204,"Chl a (µg L-1)","biom","biom","SS",NA,0.309294787,NA,0.178571429,3,19.88296289,NA,33.67119858,NA,1.6378,"Chl a (µg L-1)",2,NA,1.679028844,NA,0.969387755,3,0.8,1.207228463,0.405719326,0.680384014
"2972",2972,2988,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",28,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,41.82126174,NA,100,NA,1.204081633,"Chl a (µg L-1)","biom","biom","SS",NA,0.220924848,NA,0.12755102,3,18.51239669,NA,44.26551453,NA,2.4031,"Chl a (µg L-1)",2,NA,0.662774544,NA,0.382653061,3,0.8,0.494002978,1.941655651,0.980835556
"2973",2973,2989,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",0,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,48.76033058,NA,100,NA,5.158163265,"Chl a (µg L-1)","biom","biom","SS",NA,0.574404605,NA,0.331632653,3,14.0526667,NA,28.81987578,NA,4.1633,"Chl a (µg L-1)",2,NA,0.176739878,NA,0.102040816,3,0.8,0.42495743,-1.872936703,0.958990991
"2974",2974,2990,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",4,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.86181408,NA,100,NA,2.964285714,"Chl a (µg L-1)","biom","biom","SS",NA,0.397664726,NA,0.229591837,3,12.68518043,NA,24.45957716,NA,2.1735,"Chl a (µg L-1)",2,NA,0.397664726,NA,0.229591837,3,0.8,0.397664726,-1.590920742,0.877585734
"2975",2975,2991,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",7,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.86181408,NA,100,NA,3.831632653,"Chl a (µg L-1)","biom","biom","SS",NA,0.265109817,NA,0.153061224,3,12.68518043,NA,24.45957716,NA,1.5612,"Chl a (µg L-1)",2,NA,0.132554909,NA,0.076530612,3,0.8,0.209587713,-8.666188021,6.925234568
"2976",2976,2992,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",10,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,2.887755102,"Chl a (µg L-1)","biom","biom","SS",NA,0.486034665,NA,0.280612245,3,7.849699707,NA,15.10171835,NA,0.9235,"Chl a (µg L-1)",2,NA,0.132554909,NA,0.076530612,3,0.8,0.356230613,-4.411267624,2.288273504
"2977",2977,2993,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",14,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,2.071428571,"Chl a (µg L-1)","biom","biom","SS",NA,0.220924848,NA,0.12755102,3,7.849699707,NA,15.10171835,NA,0.7959,"Chl a (µg L-1)",2,NA,0.176739878,NA,0.102040816,3,0.8,0.200055958,-5.100613705,2.834688347
"2978",2978,2994,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",17,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,49.13300139,NA,100,NA,2.045918367,"Chl a (µg L-1)","biom","biom","SS",NA,0.132554909,NA,0.076530612,3,5.000769981,NA,10.17802666,NA,1.0255,"Chl a (µg L-1)",2,NA,0.176739878,NA,0.102040816,3,0.8,0.156217458,-5.225578118,2.942222222
"2979",2979,2995,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",21,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,49.13300139,NA,100,NA,2.403061224,"Chl a (µg L-1)","biom","biom","SS",NA,0.751144483,NA,0.433673469,3,5.000769981,NA,10.17802666,NA,1.3061,"Chl a (µg L-1)",2,NA,0.176739878,NA,0.102040816,3,0.8,0.545644123,-1.608284563,0.882214936
"2980",2980,2996,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",24,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,47.77167497,NA,100,NA,1.204081633,"Chl a (µg L-1)","biom","biom","SS",NA,0.309294787,NA,0.178571429,3,4.628099174,NA,9.687956675,NA,0.8469,"Chl a (µg L-1)",2,NA,0.353479757,NA,0.204081633,3,0.8,0.332122872,-0.860266817,0.72833825
"2981",2981,2997,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",2,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",28,"microcosm","culture flask",20001,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,47.77167497,NA,101,NA,1.204081633,"Chl a (µg L-1)","biom","biom","SS",NA,0.220924848,NA,0.12755102,3,4.628099174,NA,9.687956675,NA,1.102,"Chl a (µg L-1)",2,NA,0.357142857,NA,0.178571429,4,0.842105263,0.309925358,-0.277257431,0.588824168
"2982",2982,2998,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",0,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.2365895,NA,100,NA,3.09787234,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.530544895,NA,0.306310238,3,32.89256198,NA,64.19740718,NA,2.5191,"Primary Production (µg CL-1d-1)",1,NA,0.294943149,NA,0.170285506,3,0.8,0.429225667,-1.078637086,0.763621497
"2983",2983,2999,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",4,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.2365895,NA,100,NA,0.784797236,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.176890295,NA,0.10212766,3,32.89256198,NA,64.19740718,NA,0.3593,"Primary Production (µg CL-1d-1)",1,NA,0.324298875,NA,0.187234043,3,0.8,0.261208668,-1.303047644,0.808161097
"2984",2984,3000,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",7,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,50.86699861,NA,100,NA,1.008474268,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.294943149,NA,0.170285506,3,29.54776449,NA,58.08827982,NA,1.1278,"Primary Production (µg CL-1d-1)",1,NA,0.117548893,NA,0.067866885,3,0.8,0.224509692,0.425084249,0.681724718
"2985",2985,3001,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",10,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,50.86699861,NA,100,NA,0.755046372,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.265335443,NA,0.153191489,3,29.54776449,NA,58.08827982,NA,0.7721,"Primary Production (µg CL-1d-1)",1,NA,0.265083462,NA,0.153046008,3,0.8,0.265209483,0.051563819,0.666888236
"2986",2986,3002,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",14,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,0.842553191,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.206372011,NA,0.119148936,3,24.70920384,NA,46.64160304,NA,0.7404,"Primary Production (µg CL-1d-1)",1,NA,0.235727737,NA,0.136097472,3,0.8,0.221536648,-0.368797345,0.678000957
"2987",2987,3003,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",17,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,0.827350427,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.176890295,NA,0.10212766,3,24.70920384,NA,46.64160304,NA,1.0656,"Primary Production (µg CL-1d-1)",1,NA,0.294943149,NA,0.170285506,3,0.8,0.243188854,0.783910506,0.717876307
"2988",2988,3004,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",21,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,59.05035676,NA,100,NA,0.693653392,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.206372011,NA,0.119148936,3,19.88296289,NA,33.67119858,NA,0.8979,"Primary Production (µg CL-1d-1)",1,NA,0.412744022,NA,0.238297872,3,0.8,0.3263028,0.50077491,0.687564626
"2989",2989,3005,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",24,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,59.05035676,NA,100,NA,0.406037461,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.235979717,NA,0.136242953,3,19.88296289,NA,33.67119858,NA,1.0019,"Primary Production (µg CL-1d-1)",1,NA,0.265335443,NA,0.153191489,3,0.8,0.251086961,1.898361965,0.966981513
"2990",2990,3006,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",28,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,41.82126174,NA,100,NA,0.612838698,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.3536546,NA,0.204182579,3,18.51239669,NA,44.26551453,NA,0.6979,"Primary Production (µg CL-1d-1)",1,NA,0.471707454,NA,0.272340426,3,0.8,0.416880977,0.163180662,0.668885661
"2991",2991,3007,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",0,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,48.76033058,NA,100,NA,2.621276596,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.678079465,NA,0.391489362,3,14.0526667,NA,28.81987578,NA,1.583,"Primary Production (µg CL-1d-1)",1,NA,0.176890295,NA,0.10212766,3,0.8,0.495520906,-1.676293143,0.900829892
"2992",2992,3008,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",4,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.86181408,NA,100,NA,0.478486998,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.147282589,NA,0.085033642,3,12.68518043,NA,24.45957716,NA,0.4614,"Primary Production (µg CL-1d-1)",1,NA,0.206498001,NA,0.119221677,3,0.8,0.179351032,-0.076248313,0.66715115
"2993",2993,3009,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",7,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.86181408,NA,100,NA,2.19996363,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.324424865,NA,0.187306783,3,12.68518043,NA,24.45957716,NA,0.4468,"Primary Production (µg CL-1d-1)",1,NA,0.117926863,NA,0.068085106,3,0.8,0.244088343,-5.745849981,3.417899333
"2994",2994,3010,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",10,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,1.589088925,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.265209453,NA,0.153118749,3,7.849699707,NA,15.10171835,NA,0.3295,"Primary Production (µg CL-1d-1)",1,NA,0.117800873,NA,0.068012366,3,0.8,0.205198805,-4.910650295,2.676207194
"2995",2995,3011,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",14,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,1.029787234,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.177016285,NA,0.1022004,3,7.849699707,NA,15.10171835,NA,0.2638,"Primary Production (µg CL-1d-1)",1,NA,0.206372011,NA,0.119148936,3,0.8,0.192255263,-3.187251927,1.513214571
"2996",2996,3012,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",17,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,49.13300139,NA,100,NA,1.1678487,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.117926863,NA,0.068085106,3,5.000769981,NA,10.17802666,NA,0.4698,"Primary Production (µg CL-1d-1)",1,NA,0.118178844,NA,0.068230587,3,0.8,0.118052921,-4.730202799,2.531234876
"2997",2997,3013,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",21,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,49.13300139,NA,100,NA,0.915002728,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.383136316,NA,0.221203855,3,5.000769981,NA,10.17802666,NA,0.4212,"Primary Production (µg CL-1d-1)",1,NA,0.206498001,NA,0.119221677,3,0.8,0.307761971,-1.283491917,0.803945958
"2998",2998,3014,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",24,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,47.77167497,NA,100,NA,0.627459538,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.147282589,NA,0.085033642,3,4.628099174,NA,9.687956675,NA,0.3891,"Primary Production (µg CL-1d-1)",1,NA,0.176890295,NA,0.10212766,3,0.8,0.162761079,-1.171634469,0.781060611
"2999",2999,3015,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",28,"microcosm","culture flask",20001,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,47.77167497,NA,101,NA,0.612765957,"Primary Production (µg CL-1d-1)","PP","phys","dQ",NA,0.324298875,NA,0.187234043,3,4.628099174,NA,9.687956675,NA,0.4766,"Primary Production (µg CL-1d-1)",1,NA,0.238297872,NA,0.119148936,4,0.842105263,0.275933741,-0.415569522,0.595668907
"3000",3000,3016,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",0,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.2365895,NA,100,NA,47.93248945,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,6.431243505,NA,3.713080169,3,32.89256198,NA,64.19740718,NA,53.3333,"total phytoplankton biomass(µg CL-1)",2,NA,3.507951003,NA,2.025316456,3,0.8,5.180087512,0.834093072,0.724642604
"3001",3001,3017,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",17,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,32.40506329,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,2.923292502,NA,1.687763713,3,32.89256198,NA,62.08867873,NA,23.9662,"total phytoplankton biomass(µg CL-1)",2,NA,3.507951003,NA,2.025316456,3,0.8,3.228882105,-2.090833494,1.030965392
"3002",3002,3018,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",28,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,41.82126174,NA,100,NA,25.65400844,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,3.507951003,NA,2.025316456,3,29.54776449,NA,70.65249411,NA,46.5823,"total phytoplankton biomass(µg CL-1)",2,NA,3.507951003,NA,2.025316456,3,0.8,3.507951003,4.772762225,2.564938272
"3003",3003,3019,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",0,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,48.76033058,NA,100,NA,56.37130802,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,2.338634002,NA,1.35021097,3,29.54776449,NA,60.59795768,NA,49.9578,"total phytoplankton biomass(µg CL-1)",2,NA,5.261926504,NA,3.037974684,3,0.8,4.071675302,-1.260120542,0.798991982
"3004",3004,3020,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",17,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,49.13300139,NA,100,NA,39.83122363,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,8.769877507,NA,5.063291139,3,24.70920384,NA,50.29044256,NA,13.5021,"total phytoplankton biomass(µg CL-1)",2,NA,3.507951003,NA,2.025316456,3,0.8,6.678939726,-3.153687861,1.495478927
"3005",3005,3021,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM; Fig from Travet 2017???",NA,"Fig. 6","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",28,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,47.77167497,NA,100,NA,31.39240506,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,2.338634002,NA,1.35021097,3,24.70920384,NA,51.72354509,NA,18.2278,"total phytoplankton biomass(µg CL-1)",2,NA,5.261926504,NA,3.037974684,3,0.8,4.071675302,-2.586563218,1.22419244
"3006",3006,3022,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM",NA,"Fig. 7","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",11,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,1.245059289,"Chl a (µg L-1)","biom","biom","SS",NA,0.143767064,NA,0.083003953,3,24.70920384,NA,46.64160304,NA,2.0514,"Chl a (µg L-1)",2,NA,0.349148582,NA,0.201581028,3,0.8,0.266995975,2.415988812,1.153083495
"3007",3007,3023,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM",NA,"Fig. 7","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",11,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,1.636363636,"Chl a (µg L-1)","biom","biom","SS",NA,0.410763037,NA,0.23715415,3,7.849699707,NA,15.10171835,NA,1.0791,"Chl a (µg L-1)",2,NA,0.061614456,NA,0.035573123,3,0.8,0.293702753,-1.518030725,0.85870144
"3008",3008,3024,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM",NA,"Fig. 7","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",11,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,28.45849802,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,5.819143029,NA,3.359683794,3,24.70920384,NA,46.64160304,NA,35.3755,"total phytoplankton biomass(µg CL-1)",2,NA,11.29598353,NA,6.52173913,3,0.8,8.985033929,0.615868219,0.698274472
"3009",3009,3025,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM",NA,"Fig. 7","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",11,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,35.37549407,"total phytoplankton biomass(µg CL-1)","biom","biom","SS",NA,4.449932904,NA,2.56916996,3,7.849699707,NA,15.10171835,NA,15.2174,"total phytoplankton biomass(µg CL-1)",2,NA,6.846050623,NA,3.95256917,3,0.8,5.773660536,-2.793112292,1.31678969
"3010",3010,3026,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM",NA,"Fig. 7","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",11,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,52.97674657,NA,100,NA,0.694488189,"Primary Production (µg CL-1d-1)","productivity","phys","dQ",NA,0.20457293,NA,0.118110236,3,24.70920384,NA,46.64160304,NA,0.8693,"Primary Production (µg CL-1d-1)",1,NA,0.17184126,NA,0.099212598,3,0.8,0.188917313,0.740231362,0.712328539
"3011",3011,3027,"1075","Paczkowska, J; Brugel, S; Rowe, O; Lefebure, R; Brutemark, A; Andersson, A",2020,"Response of Coastal Phytoplankton to High Inflows of Terrestrial Matter","FRONTIERS IN MARINE SCIENCE",1,"Light manipulated via DOM",NA,"Fig. 7","summer","2012","Lab","coastal",63.55,19.933333,"Bothnian Sea","total phytoplankton","phytoplankton",11,"microcosm","culture flask",20000,NA,"Yes",NA,"light reduced","12",NA,NA,15,NA,NA,4,0.09,0.07,NA,NA,NA,2,51.97885119,NA,100,NA,0.878740157,"Primary Production (µg CL-1d-1)","productivity","phys","dQ",NA,0.26185335,NA,0.151181102,3,7.849699707,NA,15.10171835,NA,0.4346,"Primary Production (µg CL-1d-1)",1,NA,0.090012089,NA,0.051968504,3,0.8,0.195792432,-1.814552209,0.941049977
"3012",3012,3028,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,0.81589404,"biomass accumulated (g fw d-1)","biom","biom","SS",NA,0.144528743,NA,0.083443709,3,1.744075829,NA,24.86486486,NA,0.5099,"biomass accumulated (g fw d-1)",2,NA,0.160587492,NA,0.092715232,3,0.8,0.152769271,-1.602208421,0.880589319
"3013",3013,3029,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,1.168211921,"biomass accumulated (g fw d-1)","biom","biom","SS",NA,0.20876374,NA,0.120529801,3,1.17535545,NA,33.33333333,NA,1.0013,"biomass accumulated (g fw d-1)",2,NA,0.224822489,NA,0.129801325,3,0.8,0.216941755,-0.615418334,0.698228311
"3014",3014,3030,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,0.778807947,"biomass accumulated (g fw d-1)","biom","biom","SS",NA,0.192704991,NA,0.111258278,3,1.744075829,NA,24.86486486,NA,0.3801,"biomass accumulated (g fw d-1)",2,NA,0.160587492,NA,0.092715232,3,0.8,0.177374683,-1.798116805,0.936102004
"3015",3015,3031,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,1.112582781,"biomass accumulated (g fw d-1)","biom","biom","SS",NA,0.272998737,NA,0.157615894,3,1.17535545,NA,33.33333333,NA,0.751,"biomass accumulated (g fw d-1)",2,NA,0.224822489,NA,0.129801325,3,0.8,0.250073451,-1.156746237,0.778171821
"3016",3016,3032,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,5.376146789,"Net primary production (mg C mg dw-1 d-1)","biom","biom","dSS",NA,0.476711232,NA,0.275229358,3,1.744075829,NA,24.86486486,NA,2.6514,"Net primary production (mg C mg dw-1 d-1)",2,NA,0.619724601,NA,0.357798165,3,0.8,0.552861727,-3.942787872,1.96213135
"3017",3017,3033,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,6.449541284,"Net primary production (mg C mg dw-1 d-1)","biom","biom","dSS",NA,0.429040108,NA,0.247706422,3,1.17535545,NA,33.33333333,NA,2.7615,"Net primary production (mg C mg dw-1 d-1)",2,NA,0.619724601,NA,0.357798165,3,0.8,0.532979359,-5.535784197,3.22040889
"3018",3018,3034,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,2.970183486,"Net primary production (mg C mg dw-1 d-1)","biom","biom","dSS",NA,0.278081552,NA,0.160550459,3,1.744075829,NA,24.86486486,NA,0.7064,"Net primary production (mg C mg dw-1 d-1)",2,NA,0.444930483,NA,0.256880734,3,0.8,0.371007065,-4.881333394,2.652284642
"3019",3019,3035,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,2.809633028,"Net primary production (mg C mg dw-1 d-1)","biom","biom","dSS",NA,0.305889708,NA,0.176605505,3,1.17535545,NA,33.33333333,NA,0.8991,"Net primary production (mg C mg dw-1 d-1)",2,NA,0.500546794,NA,0.288990826,3,0.8,0.414798509,-3.684777874,1.798132332
"3020",3020,3036,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,84,"Pmax","phys","phys","dQ",NA,6.235382907,NA,3.6,3,1.744075829,NA,24.86486486,NA,93.6,"Pmax",1,NA,10.39230485,NA,6,3,0.8,8.569714114,0.896179254,0.733594771
"3021",3021,3037,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,90,"Pmax","phys","phys","dQ",NA,8.313843876,NA,4.8,3,1.17535545,NA,33.33333333,NA,96,"Pmax",1,NA,10.39230485,NA,6,3,0.8,9.410632285,0.51006137,0.688346883
"3022",3022,3038,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,80.4,"Pmax","phys","phys","dQ",NA,6.235382907,NA,3.6,3,1.744075829,NA,24.86486486,NA,82.8,"Pmax",1,NA,10.39230485,NA,6,3,0.8,8.569714114,0.224044813,0.670849673
"3023",3023,3039,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,80.4,"Pmax","phys","phys","dQ",NA,4.156921938,NA,2.4,3,1.17535545,NA,33.33333333,NA,85.2,"Pmax",1,NA,6.235382907,NA,3.6,3,0.8,5.29905652,0.724657302,0.71042735
"3024",3024,3040,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,1.470588235,"chl a (mg g dw)","cellular content","phys","Q",NA,0.042452226,NA,0.024509804,3,1.744075829,NA,24.86486486,NA,2.1324,"chl a (mg g dw)",1,NA,0.084904451,NA,0.049019608,3,0.8,0.067122862,7.887204828,5.850666667
"3025",3025,3041,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,1.862745098,"chl a (mg g dw)","cellular content","phys","Q",NA,0.042452226,NA,0.024509804,3,1.17535545,NA,33.33333333,NA,2.0833,"chl a (mg g dw)",1,NA,0.169808903,NA,0.098039216,3,0.8,0.123768443,1.425812462,0.836078431
"3026",3026,3042,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No",NA,"light reduced",NA,NA,NA,19.9,NA,NA,NA,NA,NA,NA,NA,NA,0,7.014218009,NA,100,NA,1.887254902,"chl a (mg g dw)","cellular content","phys","Q",NA,0.29716558,NA,0.171568627,3,1.744075829,NA,24.86486486,NA,1.7402,"chl a (mg g dw)",1,NA,0.169808903,NA,0.098039216,3,0.8,0.242014922,-0.486114896,0.686358974
"3027",3027,3043,"1089","Blain, CO; Shears, NT",2020,"Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata","LIMNOLOGY AND OCEANOGRAPHY",1,"2 light levels kelp",NA,"Fig. 1","summer","2016","field","coastal",-36.283333,NA,"Cape Rodney","Ecklonia radiata","kelp",32,"microcosm","culture flask",5,NA,"No","nut","light reduced",NA,NA,NA,19.9,NA,NA,NA,0.7,5,NA,NA,NA,2,3.526066351,NA,100,NA,1.740196078,"chl a (mg g dw)","cellular content","phys","Q",NA,0.127356677,NA,0.073529412,3,1.17535545,NA,33.33333333,NA,2.2059,"chl a (mg g dw)",1,NA,0.169808903,NA,0.098039216,3,0.8,0.150091283,2.482149606,1.180088889
"3028",3028,3044,"1100","Wu, YP; Zhang, MJ; Li, ZZ; Xu, JT; Beardall, J",2020,"Differential Responses of Growth and Photochemical Performance of Marine Diatoms to Ocean Warming and High Light Irradiance","PHOTOCHEMISTRY AND PHOTOBIOLOGY",1,"2 light levels 2 diatoms",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"T pseudonana","phytoplankton",1,"microcosm","culture flask",0.5,NA,"No",NA,"light reduced","12",NA,NA,16,NA,NA,NA,NA,NA,NA,NA,NA,0,520,NA,100,NA,1.823647661,"growth rate d-1","biom","biom","dSS",NA,0.035714286,NA,0.020619652,3,400,NA,76.92307692,NA,1.5335,"growth rate d-1",2,NA,0.026759607,NA,0.015449667,3,0.8,0.031556194,-7.355829091,5.175685135
"3029",3029,3045,"1100","Wu, YP; Zhang, MJ; Li, ZZ; Xu, JT; Beardall, J",2020,"Differential Responses of Growth and Photochemical Performance of Marine Diatoms to Ocean Warming and High Light Irradiance","PHOTOCHEMISTRY AND PHOTOBIOLOGY",1,"2 light levels 2 diatoms",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"T weisflogii","phytoplankton",1,"microcosm","culture flask",0.5,NA,"No",NA,"light reduced","12",NA,NA,16,NA,NA,NA,NA,NA,NA,NA,NA,0,520,NA,100,NA,0.9632287,"growth rate d-1","biom","biom","dSS",NA,0.059192825,NA,0.034174994,3,400,NA,76.92307692,NA,0.6135,"growth rate d-1",2,NA,0.010762332,NA,0.006213635,3,0.8,0.042541852,-6.577537533,4.272
"3030",3030,3046,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",0.208710467,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.655031413,"Fv/Fm","productivity","phys","dSS",NA,0.016483868,NA,0.009516965,3,20,NA,33.33333333,0.625271004,0.6828,"Fv/Fm",1,NA,0.04137931,NA,0.023890356,3,0.8,0.031495755,0.704277965,0.708000621
"3031",3031,3047,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",0.389734853,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.658417634,"Fv/Fm","productivity","phys","dSS",NA,0.023064636,NA,0.013316374,3,20,NA,33.33333333,0.625271004,0.6517,"Fv/Fm",1,NA,0.017241379,NA,0.009954315,3,0.8,0.020362252,-0.262976647,0.672429726
"3032",3032,3048,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",0.363184609,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.641920988,"Fv/Fm","productivity","phys","dSS",NA,0.019780641,NA,0.011420358,3,20,NA,33.33333333,0.625271004,0.6414,"Fv/Fm",1,NA,0.020689655,NA,0.011945178,3,0.8,0.020240252,-0.021409938,0.666704865
"3033",3033,3049,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1.008909239,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.635646896,"Fv/Fm","productivity","phys","dSS",NA,0.016496646,NA,0.009524343,3,20,NA,33.33333333,0.625271004,0.669,"Fv/Fm",1,NA,0.027586207,NA,0.015926904,3,0.8,0.022728156,1.17276989,0.781282434
"3034",3034,3050,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1.190927484,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.662110531,"Fv/Fm","productivity","phys","dSS",NA,0.016496646,NA,0.009524343,3,20,NA,33.33333333,0.625271004,0.7034,"Fv/Fm",1,NA,0.031034483,NA,0.017917767,3,0.8,0.024852349,1.330666825,0.81422285
"3035",3035,3051,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1.372803748,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.685277393,"Fv/Fm","productivity","phys","dSS",NA,0.019780641,NA,0.011420358,3,20,NA,33.33333333,0.625271004,0.6345,"Fv/Fm",1,NA,0.020689655,NA,0.011945178,3,0.8,0.020240252,-2.007668079,1.002560926
"3036",3036,3052,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.042948923,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.646048344,"Fv/Fm","productivity","phys","dSS",NA,0.013174316,NA,0.007606195,3,20,NA,33.33333333,0.625271004,0.6552,"Fv/Fm",1,NA,0.031034483,NA,0.017917767,3,0.8,0.02384011,0.306175422,0.674478616
"3037",3037,3053,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.198416924,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.656015334,"Fv/Fm","productivity","phys","dSS",NA,0.032980513,NA,0.019041308,3,20,NA,33.33333333,0.625271004,0.669,"Fv/Fm",1,NA,0.017241379,NA,0.009954315,3,0.8,0.026315199,0.393694401,0.67958294
"3038",3038,3054,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.45596848,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.636362475,"Fv/Fm","productivity","phys","dSS",NA,0.019767863,NA,0.011412981,3,20,NA,33.33333333,0.625271004,0.6483,"Fv/Fm",1,NA,0.013793103,NA,0.007963452,3,0.8,0.017044326,0.559172001,0.692722777
"3039",3039,3055,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.999041636,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.646521137,"Fv/Fm","productivity","phys","dSS",NA,0.02968374,NA,0.017137915,3,20,NA,33.33333333,0.625271004,0.6483,"Fv/Fm",1,NA,0.010344828,NA,0.005972589,3,0.8,0.022227684,0.063154569,0.666999042
"3040",3040,3056,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",3.179782061,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.643313811,"Fv/Fm","productivity","phys","dSS",NA,0.023077415,NA,0.013323752,3,20,NA,33.33333333,0.625271004,0.6483,"Fv/Fm",1,NA,0.013793103,NA,0.007963452,3,0.8,0.019010744,0.208810386,0.670300148
"3041",3041,3057,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",3.361232386,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.656590352,"Fv/Fm","productivity","phys","dSS",NA,0.009890321,NA,0.005710179,3,20,NA,33.33333333,0.625271004,0.631,"Fv/Fm",1,NA,0.010344828,NA,0.005972589,3,0.8,0.010120126,-2.020201654,1.006767893
"3042",3042,3058,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",4.026408263,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.501974231,"Fv/Fm","productivity","phys","dSS",NA,0.013174316,NA,0.007606195,3,20,NA,33.33333333,0.625271004,0.6138,"Fv/Fm",1,NA,0.027586207,NA,0.015926904,3,0.8,0.021616677,4.138244724,2.093755783
"3043",3043,3059,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",4.36233273,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,0.625271004,0.502140347,"Fv/Fm","productivity","phys","dSS",NA,0.013199872,NA,0.00762095,3,20,NA,33.33333333,0.625271004,0.6138,"Fv/Fm",1,NA,0.031034483,NA,0.017917767,3,0.8,0.023847178,3.745609065,1.835798939
"3044",3044,3060,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",0.153613577,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.605617978,"Fv/Fm","productivity","phys","dSS",NA,0.033707865,NA,0.019461245,3,20,NA,20,0.608988764,0.6017,"Fv/Fm",1,NA,0.034936116,NA,0.020170376,3,0.8,0.034327485,-0.090922054,0.667355568
"3045",3045,3061,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",0.844976267,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.608988764,"Fv/Fm","productivity","phys","dSS",NA,0.016853933,NA,0.009730623,3,20,NA,20,0.608988764,0.6054,"Fv/Fm",1,NA,0.012684092,NA,0.007323164,3,0.8,0.014915449,-0.191524241,0.669723461
"3046",3046,3062,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",0.998996229,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.612359551,"Fv/Fm","productivity","phys","dSS",NA,0.013483146,NA,0.007784498,3,20,NA,20,0.608988764,0.6182,"Fv/Fm",1,NA,0.031746806,NA,0.018329027,3,0.8,0.024389085,0.192680856,0.669760493
"3047",3047,3063,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1.152711402,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.598876404,"Fv/Fm","productivity","phys","dSS",NA,0.020224719,NA,0.011676747,3,20,NA,20,0.608988764,0.6215,"Fv/Fm",1,NA,0.022222764,NA,0.012830319,3,0.8,0.021247241,0.852779055,0.727269343
"3048",3048,3064,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1.825075588,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.595505618,"Fv/Fm","productivity","phys","dSS",NA,0.016853933,NA,0.009730623,3,20,NA,20,0.608988764,0.6316,"Fv/Fm",1,NA,0.015888033,NA,0.00917296,3,0.8,0.016378105,1.761174535,0.925144645
"3049",3049,3065,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1.978587568,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.602247191,"Fv/Fm","productivity","phys","dSS",NA,0.013483146,NA,0.007784498,3,20,NA,20,0.608988764,0.6285,"Fv/Fm",1,NA,0.012713352,NA,0.007340057,3,0.8,0.013103903,1.602982645,0.880796113
"3050",3050,3066,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",2.170502942,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.602247191,"Fv/Fm","productivity","phys","dSS",NA,0.013483146,NA,0.007784498,3,20,NA,20,0.608988764,0.6255,"Fv/Fm",1,NA,0.015873403,NA,0.009164513,3,0.8,0.014726849,1.261819415,0.79934902
"3051",3051,3067,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",2.861865633,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.598876404,"Fv/Fm","productivity","phys","dSS",NA,0.020224719,NA,0.011676747,3,20,NA,20,0.608988764,0.6292,"Fv/Fm",1,NA,0.019048083,NA,0.010997416,3,0.8,0.019645212,1.233905587,0.793543583
"3052",3052,3068,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3.015479209,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.598876404,"Fv/Fm","productivity","phys","dSS",NA,0.020224719,NA,0.011676747,3,20,NA,20,0.608988764,0.6293,"Fv/Fm",1,NA,0.022237394,NA,0.012838765,3,0.8,0.021254893,1.144864318,0.775892859
"3053",3053,3069,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3.20749618,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.602247191,"Fv/Fm","productivity","phys","dSS",NA,0.01011236,NA,0.005838374,3,20,NA,20,0.608988764,0.6294,"Fv/Fm",1,NA,0.034906857,NA,0.020153483,3,0.8,0.025697747,0.846548061,0.726386968
"3054",3054,3070,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3.840847394,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.497752809,"Fv/Fm","productivity","phys","dSS",NA,0.023595506,NA,0.013622872,3,20,NA,20,0.608988764,0.6204,"Fv/Fm",1,NA,0.022222764,NA,0.012830319,3,0.8,0.022919415,4.280950485,2.193878088
"3055",3055,3071,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",4.032965961,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,0.608988764,0.501123596,"Fv/Fm","productivity","phys","dSS",NA,0.016853933,NA,0.009730623,3,20,NA,20,0.608988764,0.6237,"Fv/Fm",1,NA,0.034899542,NA,0.02014926,3,0.8,0.027404681,3.578842396,1.734009408
"3056",3056,3072,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",0.152282497,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,663.0815016,"cell abundance","abundance","biom","SS",NA,250.6134809,NA,144.6917607,3,20,NA,20,584.1382551,977.7778,"cell abundance",2,NA,266.6666667,NA,153.9600718,3,0.8,258.7645918,0.972919128,0.745547636
"3057",3057,3073,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",0.781252719,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,1814.023913,"cell abundance","abundance","biom","SS",NA,249.3604135,NA,143.9683019,3,20,NA,20,584.1382551,2666.6667,"cell abundance",2,NA,355.5555556,NA,205.2800957,3,0.8,307.083351,2.221267291,1.077835698
"3058",3058,3074,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",0.981569467,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,1725.682661,"cell abundance","abundance","biom","SS",NA,332.6893959,NA,192.0783123,3,20,NA,20,584.1382551,3288.8889,"cell abundance",2,NA,355.5555556,NA,205.2800957,3,0.8,344.3123489,3.632065438,1.765991612
"3059",3059,3075,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1.183104474,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,2220.644285,"cell abundance","abundance","biom","SS",NA,333.3159296,NA,192.4400417,3,20,NA,20,584.1382551,3911.1111,"cell abundance",2,NA,355.5555556,NA,205.2800957,3,0.8,344.6151927,3.924300174,1.950010988
"3060",3060,3076,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1.81311892,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,3871.560591,"cell abundance","abundance","biom","SS",NA,333.3159296,NA,192.4400417,3,20,NA,20,584.1382551,6044.4444,"cell abundance",2,NA,355.5555556,NA,205.2800957,3,0.8,344.6151927,5.044197469,2.786994009
"3061",3061,3077,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1.99011469,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,4617.135697,"cell abundance","abundance","biom","SS",NA,416.644912,NA,240.5500521,3,20,NA,20,584.1382551,7111.1111,"cell abundance",2,NA,266.6666667,NA,153.9600718,3,0.8,349.7885746,5.703960839,3.377930771
"3062",3062,3078,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",2.191823735,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,5195.426304,"cell abundance","abundance","biom","SS",NA,333.9424633,NA,192.8017711,3,20,NA,20,584.1382551,7644.4444,"cell abundance",2,NA,177.7777778,NA,102.6400479,3,0.8,267.5093522,7.323910345,5.136638562
"3063",3063,3079,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",2.849510085,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,8095.650812,"cell abundance","abundance","biom","SS",NA,666.6318592,NA,384.8800834,3,20,NA,20,584.1382551,12977.7778,"cell abundance",2,NA,800,NA,461.8802154,3,0.8,736.3416448,5.304197583,3.011209333
"3064",3064,3080,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3.051915279,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,9007.257349,"cell abundance","abundance","biom","SS",NA,667.2583929,NA,385.2418128,3,20,NA,20,584.1382551,13777.7778,"cell abundance",2,NA,711.1111111,NA,410.5601914,3,0.8,689.5334565,5.53478052,3.219482951
"3065",3065,3081,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3.20332759,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,9503.472041,"cell abundance","abundance","biom","SS",NA,750.5873753,NA,433.3518232,3,20,NA,20,584.1382551,13866.6667,"cell abundance",2,NA,622.2222222,NA,359.2401675,3,0.8,689.398978,5.063186648,2.802988252
"3066",3066,3082,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3.86345046,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,13570.3023,"cell abundance","abundance","biom","SS",NA,999.9477889,NA,577.3201251,3,20,NA,20,584.1382551,13866.6667,"cell abundance",2,NA,622.2222222,NA,359.2401675,3,0.8,832.7833074,0.284697699,0.673421065
"3067",3067,3083,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 5",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",4.041316417,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,584.1382551,14732.52232,"cell abundance","abundance","biom","SS",NA,833.289824,NA,481.1001042,3,20,NA,20,584.1382551,13600,"cell abundance",2,NA,711.1111111,NA,410.5601914,3,0.8,774.6131109,-1.169639196,0.780671321
"3068",3068,3084,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",0.141843972,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,83.8150289,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,75.419,"cell abundance",2,NA,44.69273743,NA,25.80336399,3,0.8,40.00179694,-0.167913147,0.669016235
"3069",3069,3085,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",0.340425532,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,95.37572254,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,97.7654,"cell abundance",2,NA,111.7318436,NA,64.50840997,3,0.8,82.72500108,0.023109247,0.66671117
"3070",3070,3086,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1.021276596,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,83.8150289,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,153.6313,"cell abundance",2,NA,44.69273743,NA,25.80336399,3,0.8,40.00179694,1.396262395,0.829129056
"3071",3071,3087,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1.191489362,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,95.37572254,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,187.1508,"cell abundance",2,NA,33.51955307,NA,19.35252299,3,0.8,34.10577059,2.152717592,1.052849419
"3072",3072,3088,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1.361702128,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,95.37572254,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,220.6704,"cell abundance",2,NA,44.69273743,NA,25.80336399,3,0.8,40.00179694,2.505780802,1.189911452
"3073",3073,3089,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.014184397,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,130.0578035,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,399.4413,"cell abundance",2,NA,55.86592179,NA,32.25420498,3,0.8,46.49649425,4.634904918,2.456861967
"3074",3074,3090,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.156028369,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,130.0578035,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,488.8268,"cell abundance",2,NA,33.51955307,NA,19.35252299,3,0.8,34.10577059,8.415444212,6.568308441
"3075",3075,3091,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2.411347518,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,130.0578035,"cell abundance","abundance","biom","SS",NA,46.24277457,NA,26.69827834,3,20,NA,33.33333333,60.69364162,522.3464,"cell abundance",2,NA,44.69273743,NA,25.80336399,3,0.8,45.47436079,6.901270227,4.635627562
"3076",3076,3092,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",3.007092199,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,153.1791908,"cell abundance","abundance","biom","SS",NA,46.24277457,NA,26.69827834,3,20,NA,33.33333333,60.69364162,913.4078,"cell abundance",2,NA,89.38547486,NA,51.60672797,3,0.8,71.16234017,8.546415182,6.753434372
"3077",3077,3093,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",3.14893617,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,176.300578,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,1025.1397,"cell abundance",2,NA,89.38547486,NA,51.60672797,3,0.8,67.79605392,10.01638341,9.027328044
"3078",3078,3094,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",3.34751773,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,199.4219653,"cell abundance","abundance","biom","SS",NA,23.12138728,NA,13.34913917,3,20,NA,33.33333333,60.69364162,1058.6592,"cell abundance",2,NA,89.38547486,NA,51.60672797,3,0.8,65.28537993,10.52900056,9.904987737
"3079",3079,3095,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",4,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,257.2254335,"cell abundance","abundance","biom","SS",NA,34.68208092,NA,20.02370876,3,20,NA,33.33333333,60.69364162,1885.4749,"cell abundance",2,NA,156.424581,NA,90.31177395,3,0.8,113.2949608,11.49741818,11.68255206
"3080",3080,3096,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",4.340425532,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,291.9075145,"cell abundance","abundance","biom","SS",NA,46.24277457,NA,26.69827834,3,20,NA,33.33333333,60.69364162,1885.4749,"cell abundance",2,NA,189.9441341,NA,109.6642969,3,0.8,138.2338024,9.222446712,7.754460279
"3081",3081,3097,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Fig. 3",NA,NA,"Lab","Lab",NA,NA,NA,"Tetraselmis viridis","phytoplankton",4.992907801,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,60.69364162,349.7109827,"cell abundance","abundance","biom","SS",NA,46.24277457,NA,26.69827834,3,20,NA,33.33333333,60.69364162,1896.648,"cell abundance",2,NA,178.7709497,NA,103.2134559,3,0.8,130.5707599,9.477999905,8.15270685
"3082",3082,3098,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.24,"growth rate","biom","biom","dSS",NA,0.04,NA,0.023094011,3,20,NA,20,NA,0.88,"growth rate",2,NA,0.15,NA,0.08660254,3,0.8,0.109772492,4.664192191,2.4795574
"3083",3083,3099,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",2,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.24,"growth rate","biom","biom","dSS",NA,0.05,NA,0.028867513,3,20,NA,20,NA,0.87,"growth rate",2,NA,0.17,NA,0.098149546,3,0.8,0.125299641,4.022357898,2.014946921
"3084",3084,3100,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",3,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.48,"growth rate","biom","biom","dSS",NA,0.09,NA,0.051961524,3,20,NA,20,NA,0.81,"growth rate",2,NA,0.15,NA,0.08660254,3,0.8,0.123693169,2.1343135,1.04627451
"3085",3085,3101,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",4,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.24,"growth rate","biom","biom","dSS",NA,0.04,NA,0.023094011,3,20,NA,20,NA,0.72,"growth rate",2,NA,0.13,NA,0.075055535,3,0.8,0.09617692,3.992641881,1.995099099
"3086",3086,3102,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",5,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,0.1,"growth rate","biom","biom","dSS",NA,0.03,NA,0.017320508,3,20,NA,20,NA,0,"growth rate",2,NA,0,NA,0,3,0.8,0.021213203,-3.771236166,1.851851852
"3087",3087,3103,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","Lab",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,100,NA,100,NA,-0.36,"growth rate","biom","biom","dSS",NA,-0.07,NA,-0.040414519,3,20,NA,20,NA,NA,"growth rate",2,NA,NA,NA,NA,3,0.8,NA,NA,NA
"3088",3088,3104,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Tetraselmis viridis","phytoplankton",1,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,NA,0.91,"growth rate","biom","biom","dSS",NA,0.02,NA,0.011547005,3,20,NA,33.33333333,NA,1.39,"growth rate",2,NA,0.09,NA,0.051961524,3,0.8,0.065192024,5.890291114,3.557960784
"3089",3089,3105,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Tetraselmis viridis","phytoplankton",2,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,NA,0.87,"growth rate","biom","biom","dSS",NA,0.07,NA,0.040414519,3,20,NA,33.33333333,NA,0.78,"growth rate",2,NA,0.06,NA,0.034641016,3,0.8,0.065192024,-1.104429584,0.768313725
"3090",3090,3106,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Tetraselmis viridis","phytoplankton",3,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,NA,0.63,"growth rate","biom","biom","dSS",NA,0.04,NA,0.023094011,3,20,NA,33.33333333,NA,0.67,"growth rate",2,NA,0.03,NA,0.017320508,3,0.8,0.035355339,0.90509668,0.734933333
"3091",3091,3107,"1107","Stelmakh, LV; Stepanova, OA",2020,"Effect of Viral Infection on the Functioning and Lysis of Black Sea MicroalgaeTetraselmis viridis(Chlorophyta) andPhaeodactylum tricornutum(Bacillariophyta)","INLAND WATER BIOLOGY",1,"2 light levels 2 microalgae",NA,"Table 1",NA,NA,"Lab","culture",NA,NA,NA,"Tetraselmis viridis","phytoplankton",4,"microcosm","culture flask",0.05,NA,"No",NA,"light reduced",NA,NA,NA,18,NA,NA,NA,NA,NA,NA,NA,NA,0,60,NA,100,NA,0.49,"growth rate","biom","biom","dSS",NA,0.03,NA,0.017320508,3,20,NA,33.33333333,NA,0,"growth rate",2,NA,0,NA,0,3,0.8,0.021213203,-18.47905722,29.12296296
"3092",3092,3108,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,0.580652335,"growth rate","biom","biom","dSS",NA,0.040935673,NA,0.020467836,4,0,NA,0,NA,0.246,"growth rate",2,NA,0.098245614,NA,0.049122807,4,0.869565217,0.075259318,-3.86645415,1.434341731
"3093",3093,3109,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,0.580652335,"growth rate","biom","biom","dSS",NA,0.040935673,NA,0.020467836,4,42.25352113,NA,1.587301587,NA,0.7864,"growth rate",2,NA,0.040935673,NA,0.020467836,4,0.869565217,0.040935673,4.371096142,1.694155093
"3094",3094,3110,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,0.580652335,"growth rate","biom","biom","dSS",NA,0.040935673,NA,0.020467836,4,147.8873239,NA,5.555555556,NA,0.9996,"growth rate",2,NA,0.032748538,NA,0.016374269,4,0.869565217,0.037068828,9.827256197,6.535935272
"3095",3095,3111,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,0.580652335,"growth rate","biom","biom","dSS",NA,0.040935673,NA,0.020467836,4,845.0704225,NA,31.74603175,NA,1.1243,"growth rate",2,NA,0.032633226,NA,0.016316613,4,0.869565217,0.037017947,12.77159413,10.69460105
"3096",3096,3112,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,0.580652335,"growth rate","biom","biom","dSS",NA,0.040935673,NA,0.020467836,4,1436.619718,NA,53.96825397,NA,1.1341,"growth rate",2,NA,0.049122807,NA,0.024561404,4,0.869565217,0.045214928,10.6436329,7.580432582
"3097",3097,3113,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,7.205882353,"pg POC d-1 cell-1","biom","biom","SS",NA,0.441176471,NA,0.220588235,4,0,NA,0,NA,1.3235,"pg POC d-1 cell-1",2,NA,0.588235294,NA,0.294117647,4,0.869565217,0.519931457,-9.83800739,6.549149338
"3098",3098,3114,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,7.205882353,"pg POC d-1 cell-1","biom","biom","SS",NA,0.441176471,NA,0.220588235,4,42.25352113,NA,1.587301587,NA,11.4706,"pg POC d-1 cell-1",2,NA,2.794117647,NA,1.397058824,4,0.869565217,2.000216251,1.854019482,0.714836765
"3099",3099,3115,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,7.205882353,"pg POC d-1 cell-1","biom","biom","SS",NA,0.441176471,NA,0.220588235,4,147.8873239,NA,5.555555556,NA,17.0588,"pg POC d-1 cell-1",2,NA,2.5,NA,1.25,4,0.869565217,1.795081708,4.772916407,1.923795689
"3100",3100,3116,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,7.205882353,"pg POC d-1 cell-1","biom","biom","SS",NA,0.441176471,NA,0.220588235,4,845.0704225,NA,31.74603175,NA,16.7647,"pg POC d-1 cell-1",2,NA,1.911764706,NA,0.955882353,4,0.869565217,1.387350166,5.991292365,2.743474013
"3101",3101,3117,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,2661.971831,NA,100,NA,7.205882353,"pg POC d-1 cell-1","biom","biom","SS",NA,0.441176471,NA,0.220588235,4,1436.619718,NA,53.96825397,NA,14.5588,"pg POC d-1 cell-1",2,NA,0.882352941,NA,0.441176471,4,0.869565217,0.697561249,9.166022203,5.75099769
"3102",3102,3118,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,1164,NA,100,NA,0.942857143,"growth rate","biom","biom","dSS",NA,0.057142857,NA,0.028571429,4,429,NA,36.8556701,NA,0.9,"growth rate",2,NA,0.121428571,NA,0.060714286,4,0.869565217,0.094895216,-0.392718224,0.509639225
"3103",3103,3119,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Pglobosa","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,1164,NA,100,NA,0.585714286,"growth rate","biom","biom","dSS",NA,0.057142857,NA,0.028571429,4,429,NA,36.8556701,NA,0.5643,"growth rate",2,NA,0.05,NA,0.025,4,0.869565217,0.053690344,-0.347055707,0.507527979
"3104",3104,3120,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Chrysocrumulina sp.","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,1164,NA,100,NA,0.385714286,"growth rate","biom","biom","dSS",NA,0.057142857,NA,0.028571429,4,429,NA,36.8556701,NA,0.5214,"growth rate",2,NA,0.057142857,NA,0.028571429,4,0.869565217,0.057142857,2.065217391,0.76657018
"3105",3105,3121,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,1164,NA,100,NA,14.16666667,"pg POC d-1 cell-1","biom","biom","dSS",NA,1.666666667,NA,0.833333333,4,429,NA,36.8556701,NA,14.5238,"pg POC d-1 cell-1",2,NA,3.928571429,NA,1.964285714,4,0.869565217,3.017569489,0.102916936,0.500661993
"3106",3106,3122,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Pglobosa","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,1164,NA,100,NA,3.69047619,"pg POC d-1 cell-1","biom","biom","dSS",NA,0.476190476,NA,0.238095238,4,429,NA,36.8556701,NA,4.1667,"pg POC d-1 cell-1",2,NA,0.357142857,NA,0.178571429,4,0.869565217,0.420896894,0.983800739,0.560491493
"3107",3107,3123,"1121","Klintzsch, T; Langer, G; Wieland, A; Geisinger, H; Lenhart, K; Nehrke, G; Keppler, F",2020,"Effects of Temperature and Light on Methane Production of Widespread Marine Phytoplankton","JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES",1,"2 light levels",NA,"Fig. 5",NA,NA,"Lab","culture",NA,NA,NA,"Chrysocrumulina sp.","phytoplankton",7,"microcosm","culture flask",0.14,NA,"No",NA,"light gradient","8",500,NA,20,NA,NA,NA,NA,NA,NA,NA,NA,0,1164,NA,100,NA,10.71428571,"pg POC d-1 cell-1","biom","biom","dSS",NA,1.428571429,NA,0.714285714,4,429,NA,36.8556701,NA,15.4762,"pg POC d-1 cell-1",2,NA,1.666666667,NA,0.833333333,4,0.869565217,1.552191049,2.667704309,0.944790393
"3108",3108,3124,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,10.1,NA,2,4372,NA,100,NA,0.71,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.76,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3109",3109,3125,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,20.5,NA,2,4372,NA,100,NA,0.25,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.76,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3110",3110,3126,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,31.2,NA,2,4372,NA,100,NA,0.53,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.54,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3111",3111,3127,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,41.3,NA,2,4372,NA,100,NA,0.57,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.06,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3112",3112,3128,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,51.7,NA,2,4372,NA,100,NA,0.56,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.83,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3113",3113,3129,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,10.1,NA,2,4372,NA,100,NA,0.24,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.12,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3114",3114,3130,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,20.5,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.49,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3115",3115,3131,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,31.2,NA,2,4372,NA,100,NA,0.38,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,1.4,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3116",3116,3132,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,41.3,NA,2,4372,NA,100,NA,0.13,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.55,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3117",3117,3133,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,51.7,NA,2,4372,NA,100,NA,0.09,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.52,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3118",3118,3134,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,10.1,NA,2,4372,NA,100,NA,0.09,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.27,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3119",3119,3135,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,20.5,NA,2,4372,NA,100,NA,0.18,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.91,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3120",3120,3136,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,31.2,NA,2,4372,NA,100,NA,0.27,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.13,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3121",3121,3137,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,41.3,NA,2,4372,NA,100,NA,0.38,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.08,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3122",3122,3138,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,51.7,NA,2,4372,NA,100,NA,0.17,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.52,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3123",3123,3139,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,10.1,NA,2,4372,NA,100,NA,0.55,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.13,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3124",3124,3140,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,20.5,NA,2,4372,NA,100,NA,0.15,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.22,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3125",3125,3141,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,31.2,NA,2,4372,NA,100,NA,0.38,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3126",3126,3142,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,41.3,NA,2,4372,NA,100,NA,1.44,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,1.05,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3127",3127,3143,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,51.7,NA,2,4372,NA,100,NA,0.44,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.72,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3128",3128,3144,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,10.1,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.12,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3129",3129,3145,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,20.5,NA,2,4372,NA,100,NA,0.66,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.45,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3130",3130,3146,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,31.2,NA,2,4372,NA,100,NA,0.19,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.45,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3131",3131,3147,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,41.3,NA,2,4372,NA,100,NA,0.28,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.51,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3132",3132,3148,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,51.7,NA,2,4372,NA,100,NA,0.19,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.42,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3133",3133,3149,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,10.1,NA,2,4372,NA,100,NA,0.53,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.2,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3134",3134,3150,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,20.5,NA,2,4372,NA,100,NA,0.64,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.51,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3135",3135,3151,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,31.2,NA,2,4372,NA,100,NA,0.82,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.22,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3136",3136,3152,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,41.3,NA,2,4372,NA,100,NA,0.26,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.55,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3137",3137,3153,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,51.7,NA,2,4372,NA,100,NA,NA,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.22,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3138",3138,3154,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,10.1,NA,2,4372,NA,100,NA,0.8,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3139",3139,3155,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,20.5,NA,2,4372,NA,100,NA,0.22,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.44,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3140",3140,3156,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,31.2,NA,2,4372,NA,100,NA,0.08,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.24,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3141",3141,3157,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,41.3,NA,2,4372,NA,100,NA,0.12,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.19,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3142",3142,3158,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,51.7,NA,2,4372,NA,100,NA,0.21,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.2,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3143",3143,3159,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,10.1,NA,2,4372,NA,100,NA,0.06,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.61,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3144",3144,3160,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,20.5,NA,2,4372,NA,100,NA,0.26,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.3,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3145",3145,3161,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,31.2,NA,2,4372,NA,100,NA,0.26,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.34,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3146",3146,3162,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,41.3,NA,2,4372,NA,100,NA,0.21,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.46,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3147",3147,3163,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,51.7,NA,2,4372,NA,100,NA,0.28,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3148",3148,3164,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,10.1,NA,2,4372,NA,100,NA,0.15,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.32,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3149",3149,3165,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,20.5,NA,2,4372,NA,100,NA,0.23,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3150",3150,3166,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,31.2,NA,2,4372,NA,100,NA,0.29,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3151",3151,3167,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,41.3,NA,2,4372,NA,100,NA,0.3,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.64,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3152",3152,3168,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,51.7,NA,2,4372,NA,100,NA,0.21,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3153",3153,3169,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,10.1,NA,2,4372,NA,100,NA,0.17,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.18,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3154",3154,3170,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,20.5,NA,2,4372,NA,100,NA,0.24,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.17,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3155",3155,3171,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,31.2,NA,2,4372,NA,100,NA,0.31,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.28,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3156",3156,3172,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,41.3,NA,2,4372,NA,100,NA,0.35,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.23,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3157",3157,3173,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"open ocean","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,51.7,NA,2,4372,NA,100,NA,0.8,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.24,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3158",3158,3174,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,10.1,NA,2,4372,NA,100,NA,0.53,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.25,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3159",3159,3175,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,20.5,NA,2,4372,NA,100,NA,0.48,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.36,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3160",3160,3176,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,31.2,NA,2,4372,NA,100,NA,0.42,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.31,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3161",3161,3177,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,41.3,NA,2,4372,NA,100,NA,0.79,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.32,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3162",3162,3178,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,51.7,NA,2,4372,NA,100,NA,0.27,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.76,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3163",3163,3179,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,10.1,NA,2,4372,NA,100,NA,0.84,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.48,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3164",3164,3180,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,20.5,NA,2,4372,NA,100,NA,0.58,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.35,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3165",3165,3181,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,31.2,NA,2,4372,NA,100,NA,0.49,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.34,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3166",3166,3182,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,41.3,NA,2,4372,NA,100,NA,0.46,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.22,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3167",3167,3183,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,51.7,NA,2,4372,NA,100,NA,0.64,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.42,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3168",3168,3184,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,10.1,NA,2,4372,NA,100,NA,0.29,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.23,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3169",3169,3185,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,20.5,NA,2,4372,NA,100,NA,0.23,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.3,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3170",3170,3186,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,31.2,NA,2,4372,NA,100,NA,0.37,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.23,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3171",3171,3187,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,41.3,NA,2,4372,NA,100,NA,0.94,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.38,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3172",3172,3188,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,51.7,NA,2,4372,NA,100,NA,0.19,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.19,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3173",3173,3189,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,10.1,NA,2,4372,NA,100,NA,0.25,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.19,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3174",3174,3190,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,20.5,NA,2,4372,NA,100,NA,0.31,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.3,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3175",3175,3191,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,31.2,NA,2,4372,NA,100,NA,0.47,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.55,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3176",3176,3192,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,41.3,NA,2,4372,NA,100,NA,0.4,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.33,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3177",3177,3193,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,51.7,NA,2,4372,NA,100,NA,0.31,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.43,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3178",3178,3194,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,10.1,NA,2,4372,NA,100,NA,0.43,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.64,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3179",3179,3195,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,20.5,NA,2,4372,NA,100,NA,0.45,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.38,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3180",3180,3196,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,31.2,NA,2,4372,NA,100,NA,0.47,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.27,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3181",3181,3197,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,41.3,NA,2,4372,NA,100,NA,0.26,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.26,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3182",3182,3198,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,51.7,NA,2,4372,NA,100,NA,0.26,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.46,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3183",3183,3199,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,10.1,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.35,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3184",3184,3200,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,20.5,NA,2,4372,NA,100,NA,0.26,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.29,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3185",3185,3201,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,31.2,NA,2,4372,NA,100,NA,0.39,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,1.1,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3186",3186,3202,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,41.3,NA,2,4372,NA,100,NA,0.39,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.36,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3187",3187,3203,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,51.7,NA,2,4372,NA,100,NA,1.07,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.35,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3188",3188,3204,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,10.1,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.39,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3189",3189,3205,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,20.5,NA,2,4372,NA,100,NA,0.73,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.59,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3190",3190,3206,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,31.2,NA,2,4372,NA,100,NA,0.45,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.31,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3191",3191,3207,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,41.3,NA,2,4372,NA,100,NA,0.79,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.43,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3192",3192,3208,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,51.7,NA,2,4372,NA,100,NA,0.58,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.51,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3193",3193,3209,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,10.1,NA,2,4372,NA,100,NA,0.24,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.35,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3194",3194,3210,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,20.5,NA,2,4372,NA,100,NA,1.22,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.43,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3195",3195,3211,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,31.2,NA,2,4372,NA,100,NA,0.45,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.3,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3196",3196,3212,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,41.3,NA,2,4372,NA,100,NA,0.2,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.64,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3197",3197,3213,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,51.7,NA,2,4372,NA,100,NA,0.47,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.32,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3198",3198,3214,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,10.1,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.47,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3199",3199,3215,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,20.5,NA,2,4372,NA,100,NA,0.52,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.32,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3200",3200,3216,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,31.2,NA,2,4372,NA,100,NA,1.03,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.31,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3201",3201,3217,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,41.3,NA,2,4372,NA,100,NA,0.3,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.5,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3202",3202,3218,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,51.7,NA,2,4372,NA,100,NA,0.31,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.31,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3203",3203,3219,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,10.1,NA,2,4372,NA,100,NA,0.25,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.41,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3204",3204,3220,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,20.5,NA,2,4372,NA,100,NA,0.27,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.38,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3205",3205,3221,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,31.2,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.33,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3206",3206,3222,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,41.3,NA,2,4372,NA,100,NA,0.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.45,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3207",3207,3223,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"outer fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,51.7,NA,2,4372,NA,100,NA,0.63,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.37,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3208",3208,3224,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,10.1,NA,2,4372,NA,100,NA,0.55,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.34,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3209",3209,3225,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,20.5,NA,2,4372,NA,100,NA,1.11,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.57,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3210",3210,3226,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,31.2,NA,2,4372,NA,100,NA,0.46,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.53,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3211",3211,3227,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,41.3,NA,2,4372,NA,100,NA,0.52,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.57,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3212",3212,3228,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,51.7,NA,2,4372,NA,100,NA,0.44,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.36,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3213",3213,3229,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,10.1,NA,2,4372,NA,100,NA,0.44,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.17,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3214",3214,3230,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,20.5,NA,2,4372,NA,100,NA,0.57,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.71,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3215",3215,3231,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,31.2,NA,2,4372,NA,100,NA,0.89,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.49,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3216",3216,3232,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,41.3,NA,2,4372,NA,100,NA,1.69,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.65,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3217",3217,3233,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,51.7,NA,2,4372,NA,100,NA,0.98,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.58,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3218",3218,3234,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,10.1,NA,2,4372,NA,100,NA,0.32,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.27,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3219",3219,3235,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,20.5,NA,2,4372,NA,100,NA,1.39,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.53,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3220",3220,3236,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,31.2,NA,2,4372,NA,100,NA,1.32,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.74,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3221",3221,3237,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,41.3,NA,2,4372,NA,100,NA,1.22,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.91,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3222",3222,3238,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,51.7,NA,2,4372,NA,100,NA,1.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.75,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3223",3223,3239,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,10.1,NA,2,4372,NA,100,NA,0.55,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.47,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3224",3224,3240,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,20.5,NA,2,4372,NA,100,NA,0.86,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.65,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3225",3225,3241,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,31.2,NA,2,4372,NA,100,NA,1.57,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.77,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3226",3226,3242,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,41.3,NA,2,4372,NA,100,NA,1.44,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,1.05,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3227",3227,3243,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,51.7,NA,2,4372,NA,100,NA,1.19,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.78,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3228",3228,3244,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,10.1,NA,2,4372,NA,100,NA,0.43,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.46,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3229",3229,3245,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,20.5,NA,2,4372,NA,100,NA,0.67,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.58,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3230",3230,3246,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,31.2,NA,2,4372,NA,100,NA,1.68,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.72,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3231",3231,3247,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,41.3,NA,2,4372,NA,100,NA,0.77,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.98,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3232",3232,3248,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,51.7,NA,2,4372,NA,100,NA,1.13,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.85,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3233",3233,3249,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,10.1,NA,2,4372,NA,100,NA,0.55,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.44,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3234",3234,3250,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,20.5,NA,2,4372,NA,100,NA,0.73,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.51,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3235",3235,3251,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,31.2,NA,2,4372,NA,100,NA,0.82,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.44,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3236",3236,3252,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,41.3,NA,2,4372,NA,100,NA,0.66,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.23,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3237",3237,3253,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,0.6,51.7,NA,2,4372,NA,100,NA,0.77,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.32,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3238",3238,3254,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,10.1,NA,2,4372,NA,100,NA,0.67,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.44,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3239",3239,3255,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,20.5,NA,2,4372,NA,100,NA,0.8,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.44,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3240",3240,3256,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,31.2,NA,2,4372,NA,100,NA,0.62,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.48,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3241",3241,3257,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,41.3,NA,2,4372,NA,100,NA,0.9,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.78,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3242",3242,3258,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.3,51.7,NA,2,4372,NA,100,NA,0.96,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.47,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3243",3243,3259,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,10.1,NA,2,4372,NA,100,NA,0.7,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.61,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3244",3244,3260,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,20.5,NA,2,4372,NA,100,NA,0.72,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.54,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3245",3245,3261,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,31.2,NA,2,4372,NA,100,NA,1.34,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.44,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3246",3246,3262,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,41.3,NA,2,4372,NA,100,NA,1.06,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.82,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3247",3247,3263,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,1.9,51.7,NA,2,4372,NA,100,NA,1.21,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.75,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3248",3248,3264,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,10.1,NA,2,4372,NA,100,NA,1.15,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.32,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3249",3249,3265,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,20.5,NA,2,4372,NA,100,NA,0.94,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.55,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3250",3250,3266,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,31.2,NA,2,4372,NA,100,NA,0.8,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.85,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3251",3251,3267,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,41.3,NA,2,4372,NA,100,NA,1.18,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.64,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3252",3252,3268,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,2.6,51.7,NA,2,4372,NA,100,NA,1.24,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.6,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3253",3253,3269,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,10.1,NA,2,4372,NA,100,NA,2.18,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.42,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3254",3254,3270,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,20.5,NA,2,4372,NA,100,NA,1.69,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.52,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3255",3255,3271,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,31.2,NA,2,4372,NA,100,NA,1.09,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.61,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3256",3256,3272,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,41.3,NA,2,4372,NA,100,NA,1.36,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.81,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3257",3257,3273,"1113","Mustaffa, NIH; Kallajoki, L; Hillebrand, H; Wurl, O; Striebel, M",2020,"Sea surface phytoplankton community response to nutrient and light changes","MARINE BIOLOGY",1,"Ili paper data in table",NA,"rawData","summer","2017","field","ocean",NA,NA,"mid fjord","total phytoplankton","phytoplankton",38,"microcosm","culture flask",0.2,NA,NA,NA,"light reduced",NA,NA,NA,20.2,NA,NA,NA,NA,NA,3.2,51.7,NA,2,4372,NA,100,NA,0.8,"growth rate","biom","biom","dSS",NA,NA,NA,NA,2,2724,NA,62.30558097,NA,0.61,"growth rate",2,NA,NA,NA,NA,2,0.571428571,NA,NA,NA
"3258",3258,3274,"1072","Moreno, CM; Gong, W; Cohen, NR; DeLong, K; Marchetti, A",2020,"Interactive effects of iron and light limitation on the molecular physiology of the Southern Ocean diatom Fragilariopsis kerguelensis","LIMNOLOGY AND OCEANOGRAPHY",1,"growth until saturation is reached, 2 light levels Photophysiological parameters",NA,"Fig. 1",NA,"2009","Lab","atlantic",-48,-16,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",2,NA,"No","Iron_limitation","light reduced",NA,NA,NA,4,NA,NA,NA,20,300,NA,NA,200,3,90,NA,100,NA,0.218232044,"growth rate (day-1)","biom","dSS","dSS",NA,0.013812155,NA,0.007974451,3,10,NA,11.11111111,NA,0.1381,"growth rate (day-1)",2,NA,0.020718232,NA,0.011961677,3,0.8,0.017607112,-3.639915468,1.770748718
"3259",3259,3275,"1072","Moreno, CM; Gong, W; Cohen, NR; DeLong, K; Marchetti, A",2020,"Interactive effects of iron and light limitation on the molecular physiology of the Southern Ocean diatom Fragilariopsis kerguelensis","LIMNOLOGY AND OCEANOGRAPHY",1,"growth until saturation is reached, 2 light levels Photophysiological parameters",NA,"Fig. 1",NA,"2009","Lab","atlantic",-48,-16,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",2,NA,"No","Iron_limitation","light reduced",NA,NA,NA,4,NA,NA,NA,20,300,NA,NA,200,3,90,NA,100,NA,0.066298343,"growth rate (day-1)","biom","dSS","dSS",NA,0.013812155,NA,0.007974451,3,10,NA,11.11111111,NA,0.0622,"growth rate (day-1)",2,NA,0.004143646,NA,0.002392335,3,0.8,0.010196701,-0.325097022,0.675474006
"3260",3260,3276,"1072","Moreno, CM; Gong, W; Cohen, NR; DeLong, K; Marchetti, A",2020,"Interactive effects of iron and light limitation on the molecular physiology of the Southern Ocean diatom Fragilariopsis kerguelensis","LIMNOLOGY AND OCEANOGRAPHY",1,"growth until saturation is reached, 2 light levels Photophysiological parameters",NA,"Fig. 1",NA,"2009","Lab","atlantic",-48,-16,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",2,NA,"No","Iron_limitation","light reduced",NA,NA,NA,4,NA,NA,NA,20,300,NA,NA,200,3,90,NA,100,NA,0.693922652,"Fv/Fm","productivity","dQ","dQ",NA,0.013259669,NA,0.007655473,3,10,NA,11.11111111,NA,0.7249,"Fv/Fm",1,NA,0.013259669,NA,0.007655473,3,0.8,0.013259669,1.866666667,0.957037037
"3261",3261,3277,"1072","Moreno, CM; Gong, W; Cohen, NR; DeLong, K; Marchetti, A",2020,"Interactive effects of iron and light limitation on the molecular physiology of the Southern Ocean diatom Fragilariopsis kerguelensis","LIMNOLOGY AND OCEANOGRAPHY",1,"growth until saturation is reached, 2 light levels Photophysiological parameters",NA,"Fig. 1",NA,"2009","Lab","atlantic",-48,-16,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",2,NA,"No","Iron_limitation","light reduced",NA,NA,NA,4,NA,NA,NA,20,300,NA,NA,200,3,90,NA,100,NA,0.490607735,"Fv/Fm","productivity","dQ","dQ",NA,0.022099448,NA,0.012759122,3,10,NA,11.11111111,NA,0.5657,"Fv/Fm",1,NA,0.013259669,NA,0.007655473,3,0.8,0.018223671,3.2984845,1.573333333
"3262",3262,3278,"1072","Moreno, CM; Gong, W; Cohen, NR; DeLong, K; Marchetti, A",2020,"Interactive effects of iron and light limitation on the molecular physiology of the Southern Ocean diatom Fragilariopsis kerguelensis","LIMNOLOGY AND OCEANOGRAPHY",1,"growth until saturation is reached, 2 light levels Photophysiological parameters",NA,"Fig. 1",NA,"2009","Lab","atlantic",-48,-16,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",2,NA,"No","Iron_limitation","light reduced",NA,NA,NA,4,NA,NA,NA,20,300,NA,NA,200,3,90,NA,100,NA,3.923076923,"Pmax","productivity","dQ","dQ",NA,0.230769231,NA,0.133234678,3,10,NA,11.11111111,NA,3.4615,"Pmax",1,NA,0.230769231,NA,0.133234678,3,0.8,0.230769231,-1.6,0.88
"3263",3263,3279,"1072","Moreno, CM; Gong, W; Cohen, NR; DeLong, K; Marchetti, A",2020,"Interactive effects of iron and light limitation on the molecular physiology of the Southern Ocean diatom Fragilariopsis kerguelensis","LIMNOLOGY AND OCEANOGRAPHY",1,"growth until saturation is reached, 2 light levels Photophysiological parameters",NA,"Fig. 1",NA,"2009","Lab","atlantic",-48,-16,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",2,NA,"No","Iron_limitation","light reduced",NA,NA,NA,4,NA,NA,NA,20,300,NA,NA,200,3,90,NA,100,NA,11.84615385,"Pmax","productivity","dQ","dQ",NA,0.461538462,NA,0.266469355,3,10,NA,11.11111111,NA,8.6923,"Pmax",1,NA,0.538461538,NA,0.310880914,3,0.8,0.501477108,-5.031290327,2.776156863
"3264",3264,3280,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,9.4,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,1.248809524,"specific growth rate (d-1)","biom","biom","dSS",NA,0.047619048,NA,0.023809524,4,30,NA,20,NA,0.7369,"specific growth rate (d-1)",2,NA,0.011904762,NA,0.005952381,4,0.869565217,0.034708047,-12.82511158,10.78021795
"3265",3265,3281,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,9.1,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,1.385714286,"specific growth rate (d-1)","biom","biom","dSS",NA,0.047619048,NA,0.023809524,4,30,NA,20,NA,0.7131,"specific growth rate (d-1)",2,NA,0.023809524,NA,0.011904762,4,0.869565217,0.037646163,-15.53640763,15.58624764
"3266",3266,3282,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.7,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,1.29047619,"specific growth rate (d-1)","biom","biom","dSS",NA,0.053571429,NA,0.026785714,4,30,NA,20,NA,0.969,"specific growth rate (d-1)",2,NA,0.017857143,NA,0.008928571,4,0.869565217,0.039929785,-6.999864973,3.562381853
"3267",3267,3283,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,1.367857143,"specific growth rate (d-1)","biom","biom","dSS",NA,0.017857143,NA,0.008928571,4,30,NA,20,NA,0.9036,"specific growth rate (d-1)",2,NA,0.047619048,NA,0.023809524,4,0.869565217,0.035961446,-11.22665379,8.377359712
"3268",3268,3284,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,9.5,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0,"C per cell (pg cell-1)","biom","biom","SS",NA,0.135135135,NA,0.067567568,4,30,NA,20,NA,14.5946,"C per cell (pg cell-1)",2,NA,4.189189189,NA,2.094594595,4,0.869565217,2.963744892,4.282066198,1.646005683
"3269",3269,3285,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.9,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,10.67567568,"C per cell (pg cell-1)","biom","biom","SS",NA,2.297297297,NA,1.148648649,4,30,NA,20,NA,12.7027,"C per cell (pg cell-1)",2,NA,1.351351351,NA,0.675675676,4,0.869565217,1.884638606,0.935262704,0.55466977
"3270",3270,3286,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.5,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,8.783783784,"C per cell (pg cell-1)","biom","biom","SS",NA,0.135135135,NA,0.067567568,4,30,NA,20,NA,14.1892,"C per cell (pg cell-1)",2,NA,0.135135135,NA,0.067567568,4,0.869565217,0.135135135,34.7826087,76.11436673
"3271",3271,3287,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.2,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,11.21621622,"C per cell (pg cell-1)","biom","biom","SS",NA,1.351351351,NA,0.675675676,4,30,NA,20,NA,10.9459,"C per cell (pg cell-1)",2,NA,0.810810811,NA,0.405405405,4,0.869565217,1.114352872,-0.210900544,0.50277994
"3272",3272,3288,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 2",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,7.9,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,13.51351351,"C per cell (pg cell-1)","biom","biom","SS",NA,0.27027027,NA,0.135135135,4,30,NA,20,NA,9.7297,"C per cell (pg cell-1)",2,NA,1.486486486,NA,0.743243243,4,0.869565217,1.068337047,-3.07978346,1.092816635
"3273",3273,3289,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.9,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0.353333333,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.04,NA,0.02,4,30,NA,20,NA,0.4867,"Chl a (pg cell-1)",1,NA,0.113333333,NA,0.056666667,4,0.869565217,0.084983659,1.364286157,0.616329795
"3274",3274,3290,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.5,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0.24,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.013333333,NA,0.006666667,4,30,NA,20,NA,0.32,"Chl a (pg cell-1)",1,NA,0.02,NA,0.01,4,0.869565217,0.016996732,4.092858472,1.546968155
"3275",3275,3291,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,8.2,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0.253333333,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.053333333,NA,0.026666667,4,30,NA,20,NA,0.6867,"Chl a (pg cell-1)",1,NA,0.126666667,NA,0.063333333,4,0.869565217,0.097182532,3.877359316,1.439619704
"3276",3276,3292,"S1","Bartual & Galvez",2002,"Growth and biochemical composition of the diatom Phaeodactylum tricornutum at different pH and inorganic carbon levels under saturating and subsaturating light regimes","Botanica Marina",1,"only PH treatment",NA,"Fig. 3",NA,NA,"Lab","culture",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","14",NA,NA,17.5,7.9,NA,NA,NA,NA,NA,NA,NA,0,150,NA,100,NA,0.326666667,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.066666667,NA,0.033333333,4,30,NA,20,NA,0.8467,"Chl a (pg cell-1)",1,NA,0.046666667,NA,0.023333333,4,0.869565217,0.057542255,7.858119446,4.359377577
"3277",3277,3293,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,1.111643836,"growth rate (day-1)","biom","biom","dSS",NA,0.160273973,NA,0.065431575,6,48.21428571,NA,10.77844311,NA,0.7356,"growth rate (day-1)",2,NA,0.135616438,NA,0.055365179,6,0.923076923,0.148458015,-2.338049664,0.561103176
"3278",3278,3294,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,1.111643836,"growth rate (day-1)","biom","biom","dSS",NA,0.160273973,NA,0.065431575,6,80.35714286,NA,17.96407186,NA,0.8651,"growth rate (day-1)",2,NA,0.073972603,NA,0.030199189,6,0.923076923,0.124819254,-1.823500794,0.471881464
"3279",3279,3295,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,1.111643836,"growth rate (day-1)","biom","biom","dSS",NA,0.160273973,NA,0.065431575,6,133.9285714,NA,29.94011976,NA,0.9637,"growth rate (day-1)",2,NA,0.178767123,NA,0.072981372,6,0.923076923,0.16977254,-0.804398668,0.360294051
"3280",3280,3296,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,1.111643836,"growth rate (day-1)","biom","biom","dSS",NA,0.160273973,NA,0.065431575,6,249.1071429,NA,55.68862275,NA,1.013,"growth rate (day-1)",2,NA,0.147945205,NA,0.060398377,6,0.923076923,0.154232827,-0.590297182,0.347852115
"3281",3281,3297,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,0.889726027,"growth rate (day-1)","biom","biom","dSS",NA,0.061643836,NA,0.025165991,6,48.21428571,NA,10.77844311,NA,0.8897,"growth rate (day-1)",2,NA,0.123287671,NA,0.050331981,6,0.923076923,0.097467462,0,0.333333333
"3282",3282,3298,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,0.889726027,"growth rate (day-1)","biom","biom","dSS",NA,0.061643836,NA,0.025165991,6,80.35714286,NA,17.96407186,NA,0.9637,"growth rate (day-1)",2,NA,0.080136986,NA,0.032715788,6,0.923076923,0.071490905,0.955120129,0.371343936
"3283",3283,3299,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,0.889726027,"growth rate (day-1)","biom","biom","dSS",NA,0.061643836,NA,0.025165991,6,133.9285714,NA,29.94011976,NA,1.0007,"growth rate (day-1)",2,NA,0.067808219,NA,0.02768259,6,0.923076923,0.064799371,1.580626504,0.437432506
"3284",3284,3300,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,447.3214286,NA,100,NA,0.889726027,"growth rate (day-1)","biom","biom","dSS",NA,0.061643836,NA,0.025165991,6,249.1071429,NA,55.68862275,NA,0.9575,"growth rate (day-1)",2,NA,0.110958904,NA,0.045298783,6,0.923076923,0.089754779,0.697369017,0.353596814
"3285",3285,3301,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.582550336,"growth rate (day-1)","biom","biom","dSS",NA,0.185234899,NA,0.075621831,6,20.47732266,NA,8.447556615,NA,0.9624,"growth rate (day-1)",2,NA,0.161073826,NA,0.065758114,6,0.923076923,0.173575265,-3.297886917,0.786502421
"3286",3286,3302,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.582550336,"growth rate (day-1)","biom","biom","dSS",NA,0.185234899,NA,0.075621831,6,38.96830891,NA,16.07568534,NA,1.1154,"growth rate (day-1)",2,NA,0.185234899,NA,0.075621831,6,0.923076923,0.185234899,-2.327759197,0.55910262
"3287",3287,3303,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.582550336,"growth rate (day-1)","biom","biom","dSS",NA,0.185234899,NA,0.075621831,6,76.22114545,NA,31.44368296,NA,1.3007,"growth rate (day-1)",2,NA,0.153020134,NA,0.062470208,6,0.923076923,0.169892804,-1.531531496,0.431066197
"3288",3288,3304,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.582550336,"growth rate (day-1)","biom","biom","dSS",NA,0.185234899,NA,0.075621831,6,135.2153369,NA,55.7806913,NA,1.3893,"growth rate (day-1)",2,NA,0.185234899,NA,0.075621831,6,0.923076923,0.185234899,-0.963210702,0.371990619
"3289",3289,3305,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.316778523,"growth rate (day-1)","biom","biom","dSS",NA,0.177181208,NA,0.072333925,6,20.47732266,NA,8.447556615,NA,1.0752,"growth rate (day-1)",2,NA,0.136912752,NA,0.055894397,6,0.923076923,0.158332375,-1.408589346,0.416005164
"3290",3290,3306,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.316778523,"growth rate (day-1)","biom","biom","dSS",NA,0.177181208,NA,0.072333925,6,38.96830891,NA,16.07568534,NA,1.1638,"growth rate (day-1)",2,NA,0.217449664,NA,0.088773454,6,0.923076923,0.198340033,-0.712157565,0.35446535
"3291",3291,3307,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.316778523,"growth rate (day-1)","biom","biom","dSS",NA,0.177181208,NA,0.072333925,6,76.22114545,NA,31.44368296,NA,1.3168,"growth rate (day-1)",2,NA,0.217449664,NA,0.088773454,6,0.923076923,0.198340033,0,0.333333333
"3292",3292,3308,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,242.4052728,NA,100,NA,1.316778523,"growth rate (day-1)","biom","biom","dSS",NA,0.177181208,NA,0.072333925,6,135.2153369,NA,55.7806913,NA,1.4617,"growth rate (day-1)",2,NA,0.225503356,NA,0.092061359,6,0.923076923,0.202786765,0.659881222,0.351476801
"3293",3293,3309,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.583606557,"growth rate (day-1)","biom","biom","dSS",NA,0.236065574,NA,0.096373367,6,40.22988506,NA,9.090909091,NA,0.9836,"growth rate (day-1)",2,NA,0.108196721,NA,0.044171127,6,0.923076923,0.183621194,-3.016243073,0.712405095
"3294",3294,3310,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.583606557,"growth rate (day-1)","biom","biom","dSS",NA,0.236065574,NA,0.096373367,6,80.45977011,NA,18.18181818,NA,1.318,"growth rate (day-1)",2,NA,0.186885246,NA,0.076295582,6,0.923076923,0.21290027,-1.151454709,0.388576998
"3295",3295,3311,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.583606557,"growth rate (day-1)","biom","biom","dSS",NA,0.236065574,NA,0.096373367,6,150.1915709,NA,33.93939394,NA,1.5541,"growth rate (day-1)",2,NA,0.167213115,NA,0.068264468,6,0.923076923,0.204557059,-0.133157641,0.334072123
"3296",3296,3312,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,7.68,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.583606557,"growth rate (day-1)","biom","biom","dSS",NA,0.236065574,NA,0.096373367,6,241.3793103,NA,54.54545455,NA,1.6131,"growth rate (day-1)",2,NA,0.26557377,NA,0.108420038,6,0.923076923,0.251253241,0.108409887,0.333823029
"3297",3297,3313,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.347540984,"growth rate (day-1)","biom","biom","dSS",NA,0.275409836,NA,0.112435595,6,40.22988506,NA,9.090909091,NA,1.0328,"growth rate (day-1)",2,NA,0.08852459,NA,0.036140013,6,0.923076923,0.204557059,-1.42034817,0.417391205
"3298",3298,3314,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.347540984,"growth rate (day-1)","biom","biom","dSS",NA,0.275409836,NA,0.112435595,6,80.45977011,NA,18.18181818,NA,1.5738,"growth rate (day-1)",2,NA,0.196721311,NA,0.080311139,6,0.923076923,0.239321804,0.87257924,0.365058105
"3299",3299,3315,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.347540984,"growth rate (day-1)","biom","biom","dSS",NA,0.275409836,NA,0.112435595,6,150.1915709,NA,33.93939394,NA,1.7508,"growth rate (day-1)",2,NA,0.26557377,NA,0.108420038,6,0.923076923,0.270536509,1.375996358,0.412223582
"3300",3300,3316,"S2","Gao, K., J. Xu, G. Gao, Y. Li, D. A. Hutchins, B. Huang, L. Wang, Y. Zheng, P. Jin, X. Cai, et al.",2012,"Rising CO2 and increased light exposure synergistically reduce marine primary productivity, Nature Climate Change","Nature Climate Change",1,NA,NA,"Fig. 2",NA,NA,"field","ocean",NA,NA,NA,"Skeletonema costatum","phytoplankton",7,"microcosm","semi-batch",0.05,NA,"removed","pCO2","light reduced","14",NA,NA,NA,8.02,NA,NA,NA,NA,NA,NA,NA,0,442.5287356,NA,100,NA,1.347540984,"growth rate (day-1)","biom","biom","dSS",NA,0.275409836,NA,0.112435595,6,241.3793103,NA,54.54545455,NA,1.4754,"growth rate (day-1)",2,NA,0.344262295,NA,0.140544493,6,0.923076923,0.311742767,0.378622375,0.339306454
"3301",3301,3317,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25,"Cellular cholorphyll a","cellular content","phys","Q",NA,1,NA,0.577350269,3,20,NA,4,NA,107,"Cellular cholorphyll a",1,NA,4,NA,2.309401077,3,0.8,2.915475947,22.50061437,42.85647059
"3302",3302,3318,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,12,"Cellular cholorphyll a","cellular content","phys","Q",NA,1,NA,0.577350269,3,20,NA,4,NA,387,"Cellular cholorphyll a",1,NA,72,NA,41.56921938,3,0.8,50.91659847,5.891988251,3.55962713
"3303",3303,3319,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,13,"Cellular cholorphyll a","cellular content","phys","Q",NA,3,NA,1.732050808,3,20,NA,4,NA,214,"Cellular cholorphyll a",1,NA,28,NA,16.16580754,3,0.8,19.91230775,8.075407532,6.101017234
"3304",3304,3320,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,25,"Cellular cholorphyll a","cellular content","phys","Q",NA,1,NA,0.577350269,3,200,NA,40,NA,33,"Cellular cholorphyll a",1,NA,1,NA,0.577350269,3,0.8,1,6.4,4.08
"3305",3305,3321,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,12,"Cellular cholorphyll a","cellular content","phys","Q",NA,1,NA,0.577350269,3,200,NA,40,NA,8,"Cellular cholorphyll a",1,NA,3,NA,1.732050808,3,0.8,2.236067977,-1.431083506,0.837333333
"3306",3306,3322,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,13,"Cellular cholorphyll a","cellular content","phys","Q",NA,3,NA,1.732050808,3,200,NA,40,NA,15,"Cellular cholorphyll a",1,NA,3,NA,1.732050808,3,0.8,3,0.533333333,0.69037037
"3307",3307,3323,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,15,"Cellular cholorphyll a","cellular content","phys","Q",NA,2,NA,1.154700538,3,20,NA,4,NA,NA,"Cellular cholorphyll a",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"3308",3308,3324,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,14,"Cellular cholorphyll a","cellular content","phys","Q",NA,1,NA,0.577350269,3,20,NA,4,NA,30,"Cellular cholorphyll a",1,NA,7,NA,4.041451884,3,0.8,5,2.56,1.2128
"3309",3309,3325,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,5,"Cellular cholorphyll a","cellular content","phys","Q",NA,2,NA,1.154700538,3,20,NA,4,NA,61,"Cellular cholorphyll a",1,NA,5,NA,2.886751346,3,0.8,3.807886553,11.76505638,12.20137931
"3310",3310,3326,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,15,"Cellular cholorphyll a","cellular content","phys","Q",NA,2,NA,1.154700538,3,200,NA,40,NA,15,"Cellular cholorphyll a",1,NA,2,NA,1.154700538,3,0.8,2,0,0.666666667
"3311",3311,3327,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,14,"Cellular cholorphyll a","cellular content","phys","Q",NA,1,NA,0.577350269,3,200,NA,40,NA,17,"Cellular cholorphyll a",1,NA,3,NA,1.732050808,3,0.8,2.236067977,1.073312629,0.762666667
"3312",3312,3328,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 4",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,5,"Cellular cholorphyll a","cellular content","phys","Q",NA,2,NA,1.154700538,3,200,NA,40,NA,23,"Cellular cholorphyll a",1,NA,2,NA,1.154700538,3,0.8,2,7.2,4.986666667
"3313",3313,3329,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.339622642,"growth rate (day-1)","biom","biom","dSS",NA,0.037735849,NA,0.021786803,3,20,NA,4,NA,0.0717,"growth rate (day-1)",2,NA,0.026415094,NA,0.015250762,3,0.8,0.032571088,-6.580671311,4.275436242
"3314",3314,3330,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.218867925,"growth rate (day-1)","biom","biom","dSS",NA,0.060377358,NA,0.034858884,3,20,NA,4,NA,0.3208,"growth rate (day-1)",2,NA,0.094339623,NA,0.054467007,3,0.8,0.079200347,1.029155015,0.754930004
"3315",3315,3331,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.366037736,"growth rate (day-1)","biom","biom","dSS",NA,0.147169811,NA,0.08496853,3,20,NA,4,NA,0.3925,"growth rate (day-1)",2,NA,0.056603774,NA,0.032680204,3,0.8,0.111496503,0.189531284,0.669660176
"3316",3316,3332,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.339622642,"growth rate (day-1)","biom","biom","dSS",NA,0.037735849,NA,0.021786803,3,200,NA,40,NA,0.3925,"growth rate (day-1)",2,NA,0.056603774,NA,0.032680204,3,0.8,0.048103958,0.878600285,0.730994872
"3317",3317,3333,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.218867925,"growth rate (day-1)","biom","biom","dSS",NA,0.060377358,NA,0.034858884,3,200,NA,40,NA,0.5321,"growth rate (day-1)",2,NA,0.033962264,NA,0.019608122,3,0.8,0.048983981,5.115264873,2.847161227
"3318",3318,3334,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.366037736,"growth rate (day-1)","biom","biom","dSS",NA,0.147169811,NA,0.08496853,3,200,NA,40,NA,0.2642,"growth rate (day-1)",2,NA,0.154716981,NA,0.089325891,3,0.8,0.150990559,-0.539831329,0.690951489
"3319",3319,3335,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.449056604,"growth rate (day-1)","biom","biom","dSS",NA,0.086792453,NA,0.050109646,3,20,NA,4,NA,0,"growth rate (day-1)",2,NA,0,NA,0,3,0.8,0.061371532,-5.853614397,3.522066793
"3320",3320,3336,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.652830189,"growth rate (day-1)","biom","biom","dSS",NA,0.079245283,NA,0.045752285,3,20,NA,4,NA,0.2491,"growth rate (day-1)",2,NA,0.022641509,NA,0.013072082,3,0.8,0.058277152,-5.542804655,3.226890287
"3321",3321,3337,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.520754717,"growth rate (day-1)","biom","biom","dSS",NA,0.139622642,NA,0.08061117,3,20,NA,4,NA,0.083,"growth rate (day-1)",2,NA,0.064150943,NA,0.037037564,3,0.8,0.108650415,-3.223077222,1.532352232
"3322",3322,3338,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.449056604,"growth rate (day-1)","biom","biom","dSS",NA,0.086792453,NA,0.050109646,3,200,NA,40,NA,0.3434,"growth rate (day-1)",2,NA,0.060377358,NA,0.034858884,3,0.8,0.074760803,-1.130650002,0.773197452
"3323",3323,3339,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.652830189,"growth rate (day-1)","biom","biom","dSS",NA,0.079245283,NA,0.045752285,3,200,NA,40,NA,0.5925,"growth rate (day-1)",2,NA,0.083018868,NA,0.047930966,3,0.8,0.081154012,-0.59518791,0.696187387
"3324",3324,3340,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.520754717,"growth rate (day-1)","biom","biom","dSS",NA,0.139622642,NA,0.08061117,3,200,NA,40,NA,0.3887,"growth rate (day-1)",2,NA,0.030188679,NA,0.017429442,3,0.8,0.1010095,-1.046043955,0.757850663
"3325",3325,3341,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.153846154,"POC production rate(day-1)","biom","biom","dSS",NA,0.051282051,NA,0.029607706,3,20,NA,4,NA,0.5385,"POC production rate(day-1)",2,NA,0.128205128,NA,0.074019265,3,0.8,0.097638117,-5.042167022,2.785287356
"3326",3326,3342,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.948717949,"POC production rate(day-1)","biom","biom","dSS",NA,0.205128205,NA,0.118430824,3,20,NA,4,NA,5.8974,"POC production rate(day-1)",2,NA,0.282051282,NA,0.162842384,3,0.8,0.246607488,16.05374756,22.14356757
"3327",3327,3343,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.564102564,"POC production rate(day-1)","biom","biom","dSS",NA,0.230769231,NA,0.133234678,3,20,NA,4,NA,3.641,"POC production rate(day-1)",2,NA,0.717948718,NA,0.414507886,3,0.8,0.533247034,3.115888799,1.47573025
"3328",3328,3344,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.153846154,"POC production rate(day-1)","biom","biom","dSS",NA,0.051282051,NA,0.029607706,3,200,NA,40,NA,3.4872,"POC production rate(day-1)",2,NA,0.358974359,NA,0.207253943,3,0.8,0.256410256,7.28,5.0832
"3329",3329,3345,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.948717949,"POC production rate(day-1)","biom","biom","dSS",NA,0.205128205,NA,0.118430824,3,200,NA,40,NA,2.6923,"POC production rate(day-1)",2,NA,0.128205128,NA,0.074019265,3,0.8,0.171046975,8.154904776,6.208539326
"3330",3330,3346,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,1.564102564,"POC production rate(day-1)","biom","biom","dSS",NA,0.230769231,NA,0.133234678,3,200,NA,40,NA,1.6667,"POC production rate(day-1)",2,NA,0.205128205,NA,0.118430824,3,0.8,0.218325466,0.37582094,0.678436782
"3331",3331,3347,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,2.692307692,"POC production rate(day-1)","biom","biom","dSS",NA,0.333333333,NA,0.19245009,3,20,NA,4,NA,-0.0256,"POC production rate(day-1)",2,NA,0.025641026,NA,0.014803853,3,0.8,0.236398576,-9.197851412,7.716705882
"3332",3332,3348,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.512820513,"POC production rate(day-1)","biom","biom","dSS",NA,0.435897436,NA,0.251665502,3,20,NA,4,NA,0.6923,"POC production rate(day-1)",2,NA,0.076923077,NA,0.044411559,3,0.8,0.312988606,-7.209240901,4.997762864
"3333",3333,3349,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.128205128,"POC production rate(day-1)","biom","biom","dSS",NA,0.512820513,NA,0.296077061,3,20,NA,4,NA,0.3077,"POC production rate(day-1)",2,NA,0.051282051,NA,0.029607706,3,0.8,0.364427446,-6.191658394,3.861386139
"3334",3334,3350,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,2.692307692,"POC production rate(day-1)","biom","biom","dSS",NA,0.333333333,NA,0.19245009,3,200,NA,40,NA,1.8462,"POC production rate(day-1)",2,NA,0.230769231,NA,0.133234678,3,0.8,0.286675382,-2.361287784,1.131306667
"3335",3335,3351,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.512820513,"POC production rate(day-1)","biom","biom","dSS",NA,0.435897436,NA,0.251665502,3,200,NA,40,NA,4.9231,"POC production rate(day-1)",2,NA,0.333333333,NA,0.19245009,3,0.8,0.388019127,2.907601842,1.371179039
"3336",3336,3352,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,3.128205128,"POC production rate(day-1)","biom","biom","dSS",NA,0.512820513,NA,0.296077061,3,200,NA,40,NA,3.7949,"POC production rate(day-1)",2,NA,0.179487179,NA,0.103626971,3,0.8,0.384187797,1.38820998,0.827260579
"3337",3337,3353,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,267,"maximum electron transport rate","productivity","phys","dQ",NA,29.44486373,NA,17,3,20,NA,4,NA,110,"maximum electron transport rate",1,NA,15.58845727,NA,9,3,0.8,23.55843798,-5.331423081,3.035339339
"3338",3338,3354,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,652,"maximum electron transport rate","productivity","phys","dQ",NA,211.3101985,NA,122,3,20,NA,4,NA,118,"maximum electron transport rate",1,NA,10.39230485,NA,6,3,0.8,149.5994652,-2.855625181,1.346216265
"3339",3339,3355,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,435,"maximum electron transport rate","productivity","phys","dQ",NA,45.033321,NA,26,3,20,NA,4,NA,123,"maximum electron transport rate",1,NA,13.85640646,NA,8,3,0.8,33.3166625,-7.49174681,5.343855856
"3340",3340,3356,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,267,"maximum electron transport rate","productivity","phys","dQ",NA,29.44486373,NA,17,3,200,NA,40,NA,224,"maximum electron transport rate",1,NA,25.98076211,NA,15,3,0.8,27.76688675,-1.238885738,0.794569823
"3341",3341,3357,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,652,"maximum electron transport rate","productivity","phys","dQ",NA,211.3101985,NA,122,3,200,NA,40,NA,275,"maximum electron transport rate",1,NA,12.12435565,NA,7,3,0.8,149.6646251,-2.015172255,1.005076601
"3342",3342,3358,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,435,"maximum electron transport rate","productivity","phys","dQ",NA,45.033321,NA,26,3,200,NA,40,NA,288,"maximum electron transport rate",1,NA,6.92820323,NA,4,3,0.8,32.21800739,-3.650132629,1.776955684
"3343",3343,3359,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,267,"maximum electron transport rate","productivity","phys","dQ",NA,36.37306696,NA,21,3,20,NA,4,NA,NA,"maximum electron transport rate",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"3344",3344,3360,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,676,"maximum electron transport rate","productivity","phys","dQ",NA,242.4871131,NA,140,3,20,NA,4,NA,117,"maximum electron transport rate",1,NA,8.660254038,NA,5,3,0.8,171.5735994,-2.60646161,1.23280351
"3345",3345,3361,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,665,"maximum electron transport rate","productivity","phys","dQ",NA,161.0807251,NA,93,3,20,NA,4,NA,123,"maximum electron transport rate",1,NA,13.85640646,NA,8,3,0.8,114.3219139,-3.792798644,1.865443463
"3346",3346,3362,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,267,"maximum electron transport rate","productivity","phys","dQ",NA,36.37306696,NA,21,3,200,NA,40,NA,268,"maximum electron transport rate",1,NA,29.44486373,NA,17,3,0.8,33.09078422,0.024175915,0.666715373
"3347",3347,3363,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,676,"maximum electron transport rate","productivity","phys","dQ",NA,242.4871131,NA,140,3,200,NA,40,NA,186,"maximum electron transport rate",1,NA,24.24871131,NA,14,3,0.8,172.3194708,-2.274844498,1.097909791
"3348",3348,3364,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Table 1",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,665,"maximum electron transport rate","productivity","phys","dQ",NA,161.0807251,NA,93,3,200,NA,40,NA,216,"maximum electron transport rate",1,NA,25.98076211,NA,15,3,0.8,115.3733071,-3.113371792,1.47442366
"3349",3349,3365,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.313043478,"Fv/Fm","productivity","phys","dQ",NA,0.03083004,NA,0.017799732,3,20,NA,4,NA,0.4079,"Fv/Fm",1,NA,0.007114625,NA,0.00410763,3,0.8,0.022373078,3.391993216,1.625468165
"3350",3350,3366,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.358102767,"Fv/Fm","productivity","phys","dQ",NA,0.009486166,NA,0.00547684,3,20,NA,4,NA,0.4933,"Fv/Fm",1,NA,0.009486166,NA,0.00547684,3,0.8,0.009486166,11.4,11.49666667
"3351",3351,3367,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.37944664,"Fv/Fm","productivity","phys","dQ",NA,0.004743083,NA,0.00273842,3,20,NA,4,NA,0.4862,"Fv/Fm",1,NA,0.007114625,NA,0.00410763,3,0.8,0.006046268,14.12036173,17.28205128
"3352",3352,3368,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.313043478,"Fv/Fm","productivity","phys","dQ",NA,0.03083004,NA,0.017799732,3,200,NA,40,NA,0.3296,"Fv/Fm",1,NA,0.011857708,NA,0.006846051,3,0.8,0.023356975,0.568593852,0.693608247
"3353",3353,3369,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.358102767,"Fv/Fm","productivity","phys","dQ",NA,0.009486166,NA,0.00547684,3,200,NA,40,NA,0.3534,"Fv/Fm",1,NA,0.014229249,NA,0.008215261,3,0.8,0.012092536,-0.313785816,0.674871795
"3354",3354,3370,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Fragilariopsis","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.37944664,"Fv/Fm","productivity","phys","dQ",NA,0.004743083,NA,0.00273842,3,200,NA,40,NA,0.3439,"Fv/Fm",1,NA,0.011857708,NA,0.006846051,3,0.8,0.009030561,-3.151354389,1.494252874
"3355",3355,3371,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.329644269,"Fv/Fm","productivity","phys","dQ",NA,0.021343874,NA,0.012322891,3,20,NA,4,NA,NA,"Fv/Fm",1,NA,NA,NA,NA,3,0.8,NA,NA,NA
"3356",3356,3372,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.343873518,"Fv/Fm","productivity","phys","dQ",NA,0.023715415,NA,0.013692101,3,20,NA,4,NA,0.4719,"Fv/Fm",1,NA,0.035573123,NA,0.020538152,3,0.8,0.030231341,3.388886815,1.623712821
"3357",3357,3373,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.298814229,"Fv/Fm","productivity","phys","dQ",NA,0.011857708,NA,0.006846051,3,20,NA,4,NA,0.4885,"Fv/Fm",1,NA,0.016600791,NA,0.009584471,3,0.8,0.014425524,10.52153519,9.891891892
"3358",3358,3374,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.39,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.329644269,"Fv/Fm","productivity","phys","dQ",NA,0.021343874,NA,0.012322891,3,200,NA,40,NA,0.4055,"Fv/Fm",1,NA,0.028458498,NA,0.016430521,3,0.8,0.025153996,2.413591146,1.152118519
"3359",3359,3375,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,8.02,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.343873518,"Fv/Fm","productivity","phys","dQ",NA,0.023715415,NA,0.013692101,3,200,NA,40,NA,0.453,"Fv/Fm",1,NA,0.016600791,NA,0.009584471,3,0.8,0.020469577,4.263533525,2.18147651
"3360",3360,3376,"S3","Heiden, J. P., K. Bischof, and S. Trimborn",2016,"Light intensity modulates the response of two Antarctic diatom species to ocean acidification","FRONTIERS IN MARINE SCIENCE",1,NA,NA,"Fig. 2",NA,NA,"field","Antarctica",NA,NA,NA,"Odontella","phytoplankton",10,"microcosm","culture flask",1,NA,NA,"pCO2","light reduced","16",NA,NA,4,7.76,NA,NA,NA,NA,NA,NA,NA,0,500,NA,100,NA,0.298814229,"Fv/Fm","productivity","phys","dQ",NA,0.011857708,NA,0.006846051,3,200,NA,40,NA,0.4269,"Fv/Fm",1,NA,0.002371542,NA,0.00136921,3,0.8,0.008550714,11.98152424,12.62974359
"3361",3361,3377,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,0.23,"growth rate (day-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,55,NA,22,NA,0.19,"growth rate (day-1)",2,NA,0.051961524,NA,0.03,3,0.8,0.038729833,-0.826236447,0.723555556
"3362",3362,3378,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,0.23,"growth rate (day-1)","biom","biom","dSS",NA,0.069282032,NA,0.04,3,55,NA,22,NA,0.2,"growth rate (day-1)",2,NA,0.017320508,NA,0.01,3,0.8,0.050497525,-0.475270821,0.685490196
"3363",3363,3379,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,0.15,"growth rate (day-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,55,NA,22,NA,0.19,"growth rate (day-1)",2,NA,0.034641016,NA,0.02,3,0.8,0.027386128,1.168474789,0.780444444
"3364",3364,3380,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,0.28,"growth rate (day-1)","biom","biom","dSS",NA,0.017320508,NA,0.01,3,55,NA,22,NA,0.25,"growth rate (day-1)",2,NA,0.017320508,NA,0.01,3,0.8,0.017320508,-1.385640646,0.826666667
"3365",3365,3381,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,0.29,"growth rate (day-1)","biom","biom","dSS",NA,0.034641016,NA,0.02,3,55,NA,22,NA,0.24,"growth rate (day-1)",2,NA,0.017320508,NA,0.01,3,0.8,0.027386128,-1.460593487,0.844444444
"3366",3366,3382,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,0.29,"growth rate (day-1)","biom","biom","dSS",NA,0.051961524,NA,0.03,3,55,NA,22,NA,0.27,"growth rate (day-1)",2,NA,0.017320508,NA,0.01,3,0.8,0.038729833,-0.413118224,0.680888889
"3367",3367,3383,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,2758,"POC quota pg C cell-1","biom","biom","dSS",NA,1009.785621,NA,583,3,55,NA,22,NA,1743,"POC quota pg C cell-1",2,NA,1009.785621,NA,271,3,0.8,1009.785621,-0.804131078,0.720552233
"3368",3368,3384,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,3521,"POC quota pg C cell-1","biom","biom","dSS",NA,455.5293624,NA,263,3,55,NA,22,NA,2572,"POC quota pg C cell-1",2,NA,455.5293624,NA,227,3,0.8,455.5293624,-1.666632412,0.898138633
"3369",3369,3385,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,8842,"POC quota pg C cell-1","biom","biom","dSS",NA,1808.261043,NA,1044,3,55,NA,22,NA,2224,"POC quota pg C cell-1",2,NA,1808.261043,NA,221,3,0.8,1808.261043,-2.927895848,1.381047841
"3370",3370,3386,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,2494,"POC quota pg C cell-1","biom","biom","dSS",NA,616.6100875,NA,356,3,55,NA,22,NA,2843,"POC quota pg C cell-1",2,NA,616.6100875,NA,233,3,0.8,616.6100875,0.452798301,0.683752192
"3371",3371,3387,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,2351,"POC quota pg C cell-1","biom","biom","dSS",NA,1202.04326,NA,694,3,55,NA,22,NA,2256,"POC quota pg C cell-1",2,NA,1202.04326,NA,436,3,0.8,1202.04326,-0.063225678,0.666999791
"3372",3372,3388,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,2600,"POC quota pg C cell-1","biom","biom","dSS",NA,547.3280552,NA,316,3,55,NA,22,NA,2552,"POC quota pg C cell-1",2,NA,547.3280552,NA,204,3,0.8,547.3280552,-0.07015902,0.667076857
"3373",3373,3389,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,19.1,"Chl a pg cell-1","cellular content","phys","Q",NA,2.944486373,NA,1.7,3,55,NA,22,NA,27.8,"Chl a pg cell-1",1,NA,15.06884203,NA,8.7,3,0.8,10.85679511,0.641073165,0.700914567
"3374",3374,3390,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,22.1,"Chl a pg cell-1","cellular content","phys","Q",NA,3.983716857,NA,2.3,3,55,NA,22,NA,66.2,"Chl a pg cell-1",1,NA,5.715767665,NA,3.3,3,0.8,4.926459175,7.161330024,4.940387309
"3375",3375,3391,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Gonyaulax spinifera","phytoplankton",22,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,32.6,"Chl a pg cell-1","cellular content","phys","Q",NA,10.39230485,NA,6,3,55,NA,22,NA,48.2,"Chl a pg cell-1",1,NA,7.447818473,NA,4.3,3,0.8,9.04074112,1.380417804,0.825462776
"3376",3376,3392,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,5.7,"Chl a pg cell-1","cellular content","phys","Q",NA,1.558845727,NA,0.9,3,55,NA,22,NA,19.8,"Chl a pg cell-1",1,NA,13.16358614,NA,7.6,3,0.8,9.373099807,1.203443923,0.78735644
"3377",3377,3393,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,5.5,"Chl a pg cell-1","cellular content","phys","Q",NA,0.692820323,NA,0.4,3,55,NA,22,NA,26.6,"Chl a pg cell-1",1,NA,6.75499815,NA,3.9,3,0.8,4.801562246,3.515522477,1.696574857
"3378",3378,3394,"S4","Hoins, M., T. Eberlein, C. H. Großmann, K. Brandenburg, G.-J. Reichart, B. Rost, A. Sluijs, and D. B. Van de Waal",2017,"Combined effects of ocean acidification and light or nitrogen availabilities on 13C fractionation in marine dinoflagellates","PloS One",1,NA,NA,"Table 1",NA,NA,"lab","North Sea",NA,NA,NA,"Protoceratium reticulatum","phytoplankton",43,"microcosm","culture flask",2.4,NA,NA,"pCO2","light reduced","16",NA,NA,15,NA,NA,34,6.25,100,NA,NA,NA,2,250,NA,100,NA,6.2,"Chl a pg cell-1","cellular content","phys","Q",NA,1.212435565,NA,0.7,3,55,NA,22,NA,26.9,"Chl a pg cell-1",1,NA,4.849742261,NA,2.8,3,0.8,3.534826728,4.684812375,2.495622249
"3379",3379,3395,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,21.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.9,NA,1.674315781,3,54.4595616,NA,11.77962485,NA,16.9,"POC (pg cell?1)",2,NA,0.8,NA,0.461880215,3,0.8,2.127204739,-1.579537662,0.874578269
"3380",3380,3396,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,21.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.9,NA,1.674315781,3,85.44973545,NA,18.48281179,NA,15.6,"POC (pg cell?1)",2,NA,1.1,NA,0.635085296,3,0.8,2.19317122,-2.006227311,1.002079002
"3381",3381,3397,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,21.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.9,NA,1.674315781,3,146.8631897,NA,31.76656639,NA,16.1,"POC (pg cell?1)",2,NA,1,NA,0.577350269,3,0.8,2.169101196,-1.844081782,0.950053135
"3382",3382,3398,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,21.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.9,NA,1.674315781,3,260.3741497,NA,56.3190322,NA,17.2,"POC (pg cell?1)",2,NA,2.7,NA,1.558845727,3,0.8,2.801785145,-1.113575752,0.770004246
"3383",3383,3399,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,19.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.8,NA,1.616580754,3,54.32728647,NA,11.75101369,NA,14,"POC (pg cell?1)",2,NA,1.4,NA,0.808290377,3,0.8,2.213594362,-1.843156122,0.949768707
"3384",3384,3400,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,19.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.8,NA,1.616580754,3,85.03401361,NA,18.39289099,NA,16.5,"POC (pg cell?1)",2,NA,2.6,NA,1.5011107,3,0.8,2.701851217,-0.769842539,0.716054795
"3385",3385,3401,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,19.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.8,NA,1.616580754,3,143.3484505,NA,31.00632689,NA,16,"POC (pg cell?1)",2,NA,0.7,NA,0.404145188,3,0.8,2.040833163,-1.215189975,0.78972389
"3386",3386,3402,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,19.1,"POC (pg cell?1)","biom","biom","dSS",NA,2.8,NA,1.616580754,3,259.5993953,NA,56.15145253,NA,17.9,"POC (pg cell?1)",2,NA,1.9,NA,1.096965511,3,0.8,2.392697223,-0.401220844,0.680081514
"3387",3387,3403,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,7.4,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,56.7577705,NA,10.07376242,NA,6.3,"POC (pg cell?1)",2,NA,0.7,NA,0.404145188,3,0.8,0.806225775,-1.091505664,0.765948718
"3388",3388,3404,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,7.4,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,99.15731039,NA,17.59912657,NA,4.9,"POC (pg cell?1)",2,NA,0.8,NA,0.461880215,3,0.8,0.851469318,-2.348880878,1.126436782
"3389",3389,3405,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,7.4,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,178.1650871,NA,31.62197428,NA,5.4,"POC (pg cell?1)",2,NA,0.8,NA,0.461880215,3,0.8,0.851469318,-1.879104702,0.96091954
"3390",3390,3406,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,7.4,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,311.9651922,NA,55.3697441,NA,5.2,"POC (pg cell?1)",2,NA,0.2,NA,0.115470054,3,0.8,0.651920241,-2.699716761,1.274039216
"3391",3391,3407,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,6,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,56.7577705,NA,10.07376242,NA,6.7,"POC (pg cell?1)",2,NA,1.4,NA,0.808290377,3,0.8,1.17686023,0.475842403,0.685535499
"3392",3392,3408,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,6,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,99.15731039,NA,17.59912657,NA,5.7,"POC (pg cell?1)",2,NA,1.3,NA,0.75055535,3,0.8,1.118033989,-0.214662526,0.670506667
"3393",3393,3409,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,6,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,178.1650871,NA,31.62197428,NA,5.5,"POC (pg cell?1)",2,NA,0.3,NA,0.173205081,3,0.8,0.670820393,-0.596284794,0.696296296
"3394",3394,3410,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Table 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,6,"POC (pg cell?1)","biom","biom","dSS",NA,0.9,NA,0.519615242,3,311.9651922,NA,55.3697441,NA,5.9,"POC (pg cell?1)",2,NA,1,NA,0.577350269,3,0.8,0.95131488,-0.084094133,0.667255985
"3395",3395,3411,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.817283951,"growth rate (day-1)","biom","biom","dSS",NA,0.083950617,NA,0.048468911,3,54.4595616,NA,11.77962485,NA,0.6296,"growth rate (day-1)",2,NA,0.088888889,NA,0.051320024,3,0.8,0.086455019,-1.736434253,0.91793366
"3396",3396,3412,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.817283951,"growth rate (day-1)","biom","biom","dSS",NA,0.083950617,NA,0.048468911,3,85.44973545,NA,18.48281179,NA,0.7284,"growth rate (day-1)",2,NA,0.083950617,NA,0.048468911,3,0.8,0.083950617,-0.847058824,0.726459054
"3397",3397,3413,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.817283951,"growth rate (day-1)","biom","biom","dSS",NA,0.083950617,NA,0.048468911,3,146.8631897,NA,31.76656639,NA,0.7778,"growth rate (day-1)",2,NA,0.064197531,NA,0.037064462,3,0.8,0.07472961,-0.422923904,0.681572052
"3398",3398,3414,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.817283951,"growth rate (day-1)","biom","biom","dSS",NA,0.083950617,NA,0.048468911,3,260.3741497,NA,56.3190322,NA,0.842,"growth rate (day-1)",2,NA,0.079012346,NA,0.045617799,3,0.8,0.081518884,0.242313013,0.671559633
"3399",3399,3415,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.624691358,"growth rate (day-1)","biom","biom","dSS",NA,0.162962963,NA,0.094086711,3,54.32728647,NA,11.75101369,NA,0.5951,"growth rate (day-1)",2,NA,0.103703704,NA,0.059873361,3,0.8,0.136585844,-0.173544366,0.669176471
"3400",3400,3416,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.624691358,"growth rate (day-1)","biom","biom","dSS",NA,0.162962963,NA,0.094086711,3,85.03401361,NA,18.39289099,NA,0.6198,"growth rate (day-1)",2,NA,0.128395062,NA,0.074128923,3,0.8,0.146700748,-0.026929769,0.666727101
"3401",3401,3417,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.624691358,"growth rate (day-1)","biom","biom","dSS",NA,0.162962963,NA,0.094086711,3,143.3484505,NA,31.00632689,NA,0.6593,"growth rate (day-1)",2,NA,0.074074074,NA,0.042766687,3,0.8,0.126577833,0.218476808,0.670644343
"3402",3402,3418,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,462.32,NA,100,NA,0.624691358,"growth rate (day-1)","biom","biom","dSS",NA,0.162962963,NA,0.094086711,3,259.5993953,NA,56.15145253,NA,0.6395,"growth rate (day-1)",2,NA,0.128395062,NA,0.074128923,3,0.8,0.146700748,0.080789307,0.667210576
"3403",3403,3419,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.525123153,"growth rate (day-1)","biom","biom","dSS",NA,0.216748768,NA,0.12513996,3,56.7577705,NA,10.07376242,NA,0.3675,"growth rate (day-1)",2,NA,0.172413793,NA,0.09954315,3,0.8,0.195839915,-0.643936014,0.701221133
"3404",3404,3420,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.525123153,"growth rate (day-1)","biom","biom","dSS",NA,0.216748768,NA,0.12513996,3,99.15731039,NA,17.59912657,NA,0.4463,"growth rate (day-1)",2,NA,0.15270936,NA,0.08816679,3,0.8,0.187483569,-0.336318471,0.676092509
"3405",3405,3421,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.525123153,"growth rate (day-1)","biom","biom","dSS",NA,0.216748768,NA,0.12513996,3,178.1650871,NA,31.62197428,NA,0.5054,"growth rate (day-1)",2,NA,0.167487685,NA,0.09669906,3,0.8,0.193690672,-0.081385162,0.667218629
"3406",3406,3422,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.525123153,"growth rate (day-1)","biom","biom","dSS",NA,0.216748768,NA,0.12513996,3,311.9651922,NA,55.3697441,NA,0.5744,"growth rate (day-1)",2,NA,0.147783251,NA,0.0853227,3,0.8,0.185499216,0.212447621,0.670427833
"3407",3407,3423,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.722167488,"growth rate (day-1)","biom","biom","dSS",NA,0.290640394,NA,0.16780131,3,56.7577705,NA,10.07376242,NA,0.4956,"growth rate (day-1)",2,NA,0.256157635,NA,0.14789268,3,0.8,0.273942122,-0.661748498,0.703159256
"3408",3408,3424,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.722167488,"growth rate (day-1)","biom","biom","dSS",NA,0.290640394,NA,0.16780131,3,99.15731039,NA,17.59912657,NA,0.5695,"growth rate (day-1)",2,NA,0.246305419,NA,0.1422045,3,0.8,0.269386523,-0.453502596,0.683805384
"3409",3409,3425,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.722167488,"growth rate (day-1)","biom","biom","dSS",NA,0.290640394,NA,0.16780131,3,178.1650871,NA,31.62197428,NA,0.7123,"growth rate (day-1)",2,NA,0.334975369,NA,0.19339812,3,0.8,0.31359236,-0.025133818,0.666719309
"3410",3410,3426,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 1",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,563.4217699,NA,100,NA,0.722167488,"growth rate (day-1)","biom","biom","dSS",NA,0.290640394,NA,0.16780131,3,311.9651922,NA,55.3697441,NA,0.7714,"growth rate (day-1)",2,NA,0.305418719,NA,0.17633358,3,0.8,0.298121144,0.132190782,0.668122867
"3411",3411,3427,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,10.72580645,"POC production rate(day-1)","biom","biom","dSS",NA,0.967741935,NA,0.558726067,3,60.86956522,NA,11.37748883,NA,8.4677,"POC production rate(day-1)",2,NA,0.483870968,NA,0.279363033,3,0.8,0.765067176,-2.36116732,1.131259259
"3412",3412,3428,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,10.72580645,"POC production rate(day-1)","biom","biom","dSS",NA,0.967741935,NA,0.558726067,3,97.39130435,NA,18.20398212,NA,10.4839,"POC production rate(day-1)",2,NA,0.322580645,NA,0.186242022,3,0.8,0.721312251,-0.268328157,0.672666667
"3413",3413,3429,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,10.72580645,"POC production rate(day-1)","biom","biom","dSS",NA,0.967741935,NA,0.558726067,3,164.3478261,NA,30.71921983,NA,10.2419,"POC production rate(day-1)",2,NA,1.048387097,NA,0.605286573,3,0.8,1.008870645,-0.383693168,0.678935037
"3414",3414,3430,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,10.72580645,"POC production rate(day-1)","biom","biom","dSS",NA,0.967741935,NA,0.558726067,3,301.3043478,NA,56.31856969,NA,12.4194,"POC production rate(day-1)",2,NA,2.822580645,NA,1.629617695,3,0.8,2.109915395,0.642129401,0.701027514
"3415",3415,3431,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,17.98387097,"POC production rate(day-1)","biom","biom","dSS",NA,3.790322581,NA,2.188343762,3,60.86956522,NA,11.37748883,NA,9.8387,"POC production rate(day-1)",2,NA,0.967741935,NA,0.558726067,3,0.8,2.766140788,-2.35567512,1.129100439
"3416",3416,3432,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,17.98387097,"POC production rate(day-1)","biom","biom","dSS",NA,3.790322581,NA,2.188343762,3,97.39130435,NA,18.20398212,NA,11.2097,"POC production rate(day-1)",2,NA,1.451612903,NA,0.8380891,3,0.8,2.869993492,-1.888281229,0.9638005
"3417",3417,3433,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,17.98387097,"POC production rate(day-1)","biom","biom","dSS",NA,3.790322581,NA,2.188343762,3,164.3478261,NA,30.71921983,NA,12.5,"POC production rate(day-1)",2,NA,0.725806452,NA,0.41904455,3,0.8,2.728858761,-1.607667219,0.882049491
"3418",3418,3434,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,535,NA,100,NA,17.98387097,"POC production rate(day-1)","biom","biom","dSS",NA,3.790322581,NA,2.188343762,3,301.3043478,NA,56.31856969,NA,13.7903,"POC production rate(day-1)",2,NA,2.580645161,NA,1.489936179,3,0.8,3.242396854,-1.034678622,0.755879988
"3419",3419,3435,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,2.479674797,"POC production rate(day-1)","biom","biom","dSS",NA,0.528455285,NA,0.305103801,3,57.82608696,NA,9.547738693,NA,0.8537,"growth rate (day-1)",2,NA,0.284552846,NA,0.164286662,3,0.8,0.424402704,-3.065044113,1.449541284
"3420",3420,3436,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,2.479674797,"POC production rate(day-1)","biom","biom","dSS",NA,0.528455285,NA,0.305103801,3,103.4782609,NA,17.08542714,NA,1.4634,"POC production rate(day-1)",2,NA,0.284552846,NA,0.164286662,3,0.8,0.424402704,-1.91565257,0.972477064
"3421",3421,3437,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,2.479674797,"POC production rate(day-1)","biom","biom","dSS",NA,0.528455285,NA,0.305103801,3,185.6521739,NA,30.65326633,NA,1.5854,"POC production rate(day-1)",2,NA,0.528455285,NA,0.305103801,3,0.8,0.528455285,-1.353846154,0.819408284
"3422",3422,3438,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,"ambient pCO2","Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,2.479674797,"POC production rate(day-1)","biom","biom","dSS",NA,0.528455285,NA,0.305103801,3,334.7826087,NA,55.27638191,NA,2.6016,"POC production rate(day-1)",2,NA,0.691056911,NA,0.398981893,3,0.8,0.615152274,0.158596464,0.668762737
"3423",3423,3439,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,5.650406504,"POC production rate(day-1)","biom","biom","dSS",NA,1.788617886,NA,1.032659018,3,57.82608696,NA,9.547738693,NA,2.561,"POC production rate(day-1)",2,NA,0.447154472,NA,0.258164755,3,0.8,1.303668107,-1.895838905,0.966183763
"3424",3424,3440,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,5.650406504,"POC production rate(day-1)","biom","biom","dSS",NA,1.788617886,NA,1.032659018,3,103.4782609,NA,17.08542714,NA,2.2358,"POC production rate(day-1)",2,NA,1.219512195,NA,0.704085694,3,0.8,1.53074556,-1.784560014,0.932054537
"3425",3425,3441,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,5.650406504,"POC production rate(day-1)","biom","biom","dSS",NA,1.788617886,NA,1.032659018,3,185.6521739,NA,30.65326633,NA,2.6829,"POC production rate(day-1)",2,NA,0.609756098,NA,0.352042847,3,0.8,1.336217879,-1.776644196,0.929705383
"3426",3426,3442,"S5","Jin, P., J. Ding, T. Xing, U. Riebesell, and K. Gao",2017,"High levels of solar radiation offset impacts of ocean acidification on calcifying and non-calcifying strains of Emiliania huxleyi","Marine Ecology Progress Series",1,NA,NA,"Fig. 2",NA,NA,"Lab","South Pacific",NA,NA,NA,"Emiliania huxleyi","phytoplankton",18,"microcosm","culture flask",0.25,NA,NA,"pCO2","light gradient","12",NA,NA,20,NA,NA,NA,10,110,NA,NA,NA,2,605.6521739,NA,100,NA,5.650406504,"POC production rate(day-1)","biom","biom","dSS",NA,1.788617886,NA,1.032659018,3,334.7826087,NA,55.27638191,NA,4.6341,"POC production rate(day-1)",2,NA,0.731707317,NA,0.422451416,3,0.8,1.366482627,-0.594964117,0.696165192
"3427",3427,3443,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,1.206266319,"growth rate (day-1)","biom","biom","dSS",NA,0.046997389,NA,0.027133955,3,200,NA,43.47826087,NA,1.3995,"growth rate (day-1)",2,NA,0.041775457,NA,0.024119071,3,0.8,0.04446315,3.4763437,1.673747126
"3428",3428,3444,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,1.206266319,"growth rate (day-1)","biom","biom","dSS",NA,0.046997389,NA,0.027133955,3,60,NA,13.04347826,NA,1.3264,"growth rate (day-1)",2,NA,0.052219321,NA,0.030148839,3,0.8,0.049677017,1.934165059,0.978416206
"3429",3429,3445,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,1.425587467,"growth rate (day-1)","biom","biom","dSS",NA,0.041775457,NA,0.024119071,3,200,NA,43.47826087,NA,1.5979,"growth rate (day-1)",2,NA,0.07310705,NA,0.042208375,3,0.8,0.059539187,2.315433171,1.113435897
"3430",3430,3446,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,1.425587467,"growth rate (day-1)","biom","biom","dSS",NA,0.041775457,NA,0.024119071,3,60,NA,13.04347826,NA,1.4883,"growth rate (day-1)",2,NA,0.036553525,NA,0.021104187,3,0.8,0.039251427,1.277165002,0.80259587
"3431",3431,3447,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.245098039,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.026143791,NA,0.015094125,3,60,NA,13.04347826,NA,0.3562,"Chl a (pg cell-1)",1,NA,0.013071895,NA,0.007547062,3,0.8,0.020668481,4.300697618,2.208
"3432",3432,3448,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.245098039,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.026143791,NA,0.015094125,3,60,NA,13.04347826,NA,0.4281,"Chl a (pg cell-1)",1,NA,0.016339869,NA,0.009433828,3,0.8,0.021800105,6.715803933,4.425168539
"3433",3433,3449,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.218954248,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.026143791,NA,0.015094125,3,200,NA,43.47826087,NA,0.3235,"Chl a (pg cell-1)",1,NA,0.013071895,NA,0.007547062,3,0.8,0.020668481,4.047715405,2.032
"3434",3434,3450,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 1",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.218954248,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.026143791,NA,0.015094125,3,200,NA,43.47826087,NA,0.415,"Chl a (pg cell-1)",1,NA,0.013071895,NA,0.007547062,3,0.8,0.020668481,7.589466384,5.466666667
"3435",3435,3451,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",0,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.566225417,"Fv/Fm","productivity","phys","dQ",NA,0.012907983,NA,0.007452427,3,200,NA,43.47826087,NA,0.563,"Fv/Fm",1,NA,0.014511688,NA,0.008378327,3,0.8,0.013733264,-0.187645714,0.669600909
"3436",3436,3452,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.229239968,"Fv/Fm","productivity","phys","dQ",NA,0.011285844,NA,0.006515885,3,200,NA,43.47826087,NA,0.4583,"Fv/Fm",1,NA,0.008060001,NA,0.004653444,3,0.8,0.009806475,18.68362987,29.7565021
"3437",3437,3453,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.25191304,"Fv/Fm","productivity","phys","dQ",NA,0.006456296,NA,0.003727544,3,200,NA,43.47826087,NA,0.4955,"Fv/Fm",1,NA,0.006456296,NA,0.003727544,3,0.8,0.006456296,30.17844397,76.56154003
"3438",3438,3454,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.193949239,"Fv/Fm","productivity","phys","dQ",NA,0.012907983,NA,0.007452427,3,200,NA,43.47826087,NA,0.4165,"Fv/Fm",1,NA,0.008060001,NA,0.004653444,3,0.8,0.010760568,16.54840715,23.48748159
"3439",3439,3455,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.192446918,"Fv/Fm","productivity","phys","dQ",NA,0.012898766,NA,0.007447106,3,200,NA,43.47826087,NA,0.4118,"Fv/Fm",1,NA,0.008055392,NA,0.004650783,3,0.8,0.010753314,16.31889575,22.85886321
"3440",3440,3456,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.195764928,"Fv/Fm","productivity","phys","dQ",NA,0.022585514,NA,0.013039752,3,200,NA,43.47826087,NA,0.3845,"Fv/Fm",1,NA,0.0064586,NA,0.003728874,3,0.8,0.016610523,9.088452703,7.549997712
"3441",3441,3457,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.213617668,"Fv/Fm","productivity","phys","dQ",NA,0.017737532,NA,0.010240769,3,200,NA,43.47826087,NA,0.3814,"Fv/Fm",1,NA,0.017737532,NA,0.010240769,3,0.8,0.017737532,7.565393609,5.436265038
"3442",3442,3458,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.215322757,"Fv/Fm","productivity","phys","dQ",NA,0.029037201,NA,0.016764636,3,200,NA,43.47826087,NA,0.3895,"Fv/Fm",1,NA,0.014516296,NA,0.008380988,3,0.8,0.022955194,6.070641597,3.737724116
"3443",3443,3459,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.188009078,"Fv/Fm","productivity","phys","dQ",NA,0.009672922,NA,0.005584664,3,200,NA,43.47826087,NA,0.3912,"Fv/Fm",1,NA,0.012907983,NA,0.007452427,3,0.8,0.011405732,14.25381057,17.59759297
"3444",3444,3460,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.204336455,"Fv/Fm","productivity","phys","dQ",NA,0.008064609,NA,0.004656104,3,200,NA,43.47826087,NA,0.3818,"Fv/Fm",1,NA,0.008069217,NA,0.004658765,3,0.8,0.008066914,17.59451513,26.46391357
"3445",3445,3461,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.196884757,"Fv/Fm","productivity","phys","dQ",NA,0.022580905,NA,0.013037092,3,200,NA,43.47826087,NA,0.3985,"Fv/Fm",1,NA,0.006451687,NA,0.003724883,3,0.8,0.016606046,9.712414607,8.527583125
"3446",3446,3462,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",0,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.566225417,"Fv/Fm","productivity","phys","dQ",NA,0.012907983,NA,0.007452427,3,60,NA,13.04347826,NA,0.5678,"Fv/Fm",1,NA,0.008069217,NA,0.004658765,3,0.8,0.010764021,0.119875042,0.667864169
"3447",3447,3463,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.229239968,"Fv/Fm","productivity","phys","dQ",NA,0.011285844,NA,0.006515885,3,60,NA,13.04347826,NA,0.5631,"Fv/Fm",1,NA,0.01935967,NA,0.011177311,3,0.8,0.015845616,16.85592246,24.34351015
"3448",3448,3464,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.25191304,"Fv/Fm","productivity","phys","dQ",NA,0.006456296,NA,0.003727544,3,60,NA,13.04347826,NA,0.5713,"Fv/Fm",1,NA,0.008064609,NA,0.004656104,3,0.8,0.00730485,34.97495622,102.6039636
"3449",3449,3465,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.193949239,"Fv/Fm","productivity","phys","dQ",NA,0.012907983,NA,0.007452427,3,60,NA,13.04347826,NA,0.473,"Fv/Fm",1,NA,0.008069217,NA,0.004658765,3,0.8,0.010764021,20.73803969,36.50552419
"3450",3450,3466,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.192446918,"Fv/Fm","productivity","phys","dQ",NA,0.012898766,NA,0.007447106,3,60,NA,13.04347826,NA,0.465,"Fv/Fm",1,NA,0.009677531,NA,0.005587325,3,0.8,0.011402473,19.12389176,31.143603
"3451",3451,3467,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.195764928,"Fv/Fm","productivity","phys","dQ",NA,0.022585514,NA,0.013039752,3,60,NA,13.04347826,NA,0.4683,"Fv/Fm",1,NA,0.016129218,NA,0.009312208,3,0.8,0.019624692,11.11186989,10.9561377
"3452",3452,3468,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.213617668,"Fv/Fm","productivity","phys","dQ",NA,0.017737532,NA,0.010240769,3,60,NA,13.04347826,NA,0.483,"Fv/Fm",1,NA,0.011290453,NA,0.006518546,3,0.8,0.014867655,14.49313804,18.17092086
"3453",3453,3469,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.215322757,"Fv/Fm","productivity","phys","dQ",NA,0.029037201,NA,0.016764636,3,60,NA,13.04347826,NA,0.4702,"Fv/Fm",1,NA,0.008060001,NA,0.004653444,3,0.8,0.021308715,9.567775711,8.295194338
"3454",3454,3470,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.188009078,"Fv/Fm","productivity","phys","dQ",NA,0.009672922,NA,0.005584664,3,60,NA,13.04347826,NA,0.4751,"Fv/Fm",1,NA,0.006456296,NA,0.003727544,3,0.8,0.008223417,27.92910603,65.6695803
"3455",3455,3471,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.204336455,"Fv/Fm","productivity","phys","dQ",NA,0.008064609,NA,0.004656104,3,60,NA,13.04347826,NA,0.493,"Fv/Fm",1,NA,0.008060001,NA,0.004653444,3,0.8,0.008062305,28.64818403,69.05987066
"3456",3456,3472,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.196884757,"Fv/Fm","productivity","phys","dQ",NA,0.022580905,NA,0.013037092,3,60,NA,13.04347826,NA,0.4872,"Fv/Fm",1,NA,0.004838765,NA,0.002793663,3,0.8,0.016329589,14.22308042,17.52466806
"3457",3457,3473,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",0,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.598488462,"Fv/Fm","productivity","phys","dQ",NA,0.006456296,NA,0.003727544,3,200,NA,43.47826087,NA,0.5969,"Fv/Fm",1,NA,0.004834157,NA,0.002791002,3,0.8,0.005703193,-0.225601817,0.670908015
"3458",3458,3474,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.203428611,"Fv/Fm","productivity","phys","dQ",NA,0.01612461,NA,0.009309548,3,200,NA,43.47826087,NA,0.4615,"Fv/Fm",1,NA,0.008064609,NA,0.004656104,3,0.8,0.012748352,16.19456313,22.52198958
"3459",3459,3475,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.216428761,"Fv/Fm","productivity","phys","dQ",NA,0.022580905,NA,0.013037092,3,200,NA,43.47826087,NA,0.4616,"Fv/Fm",1,NA,0.008060001,NA,0.004653444,3,0.8,0.016953774,11.56880941,11.81977927
"3460",3460,3476,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.174598786,"Fv/Fm","productivity","phys","dQ",NA,0.019350453,NA,0.011171989,3,200,NA,43.47826087,NA,0.3778,"Fv/Fm",1,NA,0.009682139,NA,0.005589986,3,0.8,0.015300063,10.62626453,10.07645815
"3461",3461,3477,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.169861404,"Fv/Fm","productivity","phys","dQ",NA,0.011290453,NA,0.006518546,3,200,NA,43.47826087,NA,0.3908,"Fv/Fm",1,NA,0.011290453,NA,0.006518546,3,0.8,0.011290453,15.6564898,21.09380606
"3462",3462,3478,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.168340649,"Fv/Fm","productivity","phys","dQ",NA,0.012907983,NA,0.007452427,3,200,NA,43.47826087,NA,0.3845,"Fv/Fm",1,NA,0.020967984,NA,0.012105871,3,0.8,0.017410806,9.931125615,8.885604666
"3463",3463,3479,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.171677093,"Fv/Fm","productivity","phys","dQ",NA,0.017737532,NA,0.010240769,3,200,NA,43.47826087,NA,0.3765,"Fv/Fm",1,NA,0.020963375,NA,0.01210321,3,0.8,0.019417558,8.439416279,6.601978927
"3464",3464,3480,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.170160947,"Fv/Fm","productivity","phys","dQ",NA,0.024193827,NA,0.013968313,3,200,NA,43.47826087,NA,0.3976,"Fv/Fm",1,NA,0.032060277,NA,0.01851001,3,0.8,0.028400727,6.406088716,4.08649772
"3465",3465,3481,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.184783235,"Fv/Fm","productivity","phys","dQ",NA,0.009672922,NA,0.005584664,3,200,NA,43.47826087,NA,NA,"Fv/Fm",1,NA,NA,NA,-0.001277103,3,0.8,NA,NA,NA
"3466",3466,3482,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.186594316,"Fv/Fm","productivity","phys","dQ",NA,0.011290453,NA,0.006518546,3,200,NA,43.47826087,NA,0.3769,"Fv/Fm",1,NA,-0.002212007,NA,-0.1135983,3,0.8,0.008135333,18.71586728,29.85697401
"3467",3467,3483,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,7.82,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.180746322,"Fv/Fm","productivity","phys","dQ",NA,0.009677531,NA,0.005587325,3,200,NA,43.47826087,NA,0.3904,"Fv/Fm",1,NA,-0.196758027,NA,0.004656104,3,0.8,0.139297121,1.204216331,0.787511414
"3468",3468,3484,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",0,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.598488462,"Fv/Fm","productivity","phys","dQ",NA,0.006456296,NA,0.003727544,3,60,NA,13.04347826,NA,0.5969,"Fv/Fm",1,NA,0.008064609,NA,0.005587325,3,0.8,0.00730485,-0.176641193,0.669266843
"3469",3469,3485,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",1,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.203428611,"Fv/Fm","productivity","phys","dQ",NA,0.01612461,NA,0.009309548,3,60,NA,13.04347826,NA,0.5712,"Fv/Fm",1,NA,0.009677531,NA,0.001865102,3,0.8,0.0132977,22.12361946,41.45454485
"3470",3470,3486,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",2,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.216428761,"Fv/Fm","productivity","phys","dQ",NA,0.022580905,NA,0.013037092,3,60,NA,13.04347826,NA,0.5777,"Fv/Fm",1,NA,0.003230452,NA,0.004656104,3,0.8,0.016129679,17.91948766,27.42566982
"3471",3471,3487,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",3,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.174598786,"Fv/Fm","productivity","phys","dQ",NA,0.019350453,NA,0.011171989,3,60,NA,13.04347826,NA,0.4714,"Fv/Fm",1,NA,0.008064609,NA,0.001865102,3,0.8,0.014823595,16.01624952,22.04335407
"3472",3472,3488,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",4,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.169861404,"Fv/Fm","productivity","phys","dQ",NA,0.011290453,NA,0.006518546,3,60,NA,13.04347826,NA,0.4699,"Fv/Fm",1,NA,0.003230452,NA,0.01210321,3,0.8,0.008303919,28.90146111,70.27453787
"3473",3473,3489,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",5,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.168340649,"Fv/Fm","productivity","phys","dQ",NA,0.012907983,NA,0.007452427,3,60,NA,13.04347826,NA,0.4635,"Fv/Fm",1,NA,0.020963375,NA,0.007447106,3,0.8,0.017408031,13.56495286,16.00066217
"3474",3474,3490,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",6,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.171677093,"Fv/Fm","productivity","phys","dQ",NA,0.017737532,NA,0.010240769,3,60,NA,13.04347826,NA,0.4797,"Fv/Fm",1,NA,0.012898766,NA,0.002791002,3,0.8,0.015508033,15.89181304,21.71247682
"3475",3475,3491,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",7,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.170160947,"Fv/Fm","productivity","phys","dQ",NA,0.024193827,NA,0.013968313,3,60,NA,13.04347826,NA,0.4831,"Fv/Fm",1,NA,0.004834157,NA,0.003719562,3,0.8,0.017445778,14.34877043,17.82393441
"3476",3476,3492,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",8,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.184783235,"Fv/Fm","productivity","phys","dQ",NA,0.009672922,NA,0.005584664,3,60,NA,13.04347826,NA,0.4783,"Fv/Fm",1,NA,0.006442471,NA,0.006518546,3,0.8,0.008217994,28.57648843,68.71797424
"3477",3477,3493,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",10,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.186594316,"Fv/Fm","productivity","phys","dQ",NA,0.011290453,NA,0.006518546,3,60,NA,13.04347826,NA,0.4801,"Fv/Fm",1,NA,0.011290453,NA,0.004653444,3,0.8,0.011290453,20.79967347,36.71886804
"3478",3478,3494,"S6","Li, G., and D. A. Campbell",2014,"Light-modulated responses of growth and photosynthetic performance to ocean acidification in the model diatom Phaeodactylum tricornutum","PloS One",1,"High and low carbon",NA,"Fig. 3",NA,NA,"lab","coastal",18,116,NA,"Phaeodactylum tricornutum","phytoplankton",16,"microcosm","culture flask",NA,NA,"No","pCO2","light gradient","12",NA,NA,20,8.18,NA,NA,NA,NA,NA,NA,NA,0,460,NA,100,NA,0.180746322,"Fv/Fm","productivity","phys","dQ",NA,0.009677531,NA,0.005587325,3,60,NA,13.04347826,NA,0.4856,"Fv/Fm",1,NA,0.008060001,NA,0.101159261,3,0.8,0.008905566,27.38442174,63.15887948
"3479",3479,3495,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,372.7326172,NA,100,NA,1.344444444,"growth rate (day-1)","biom","biom","dSS",NA,0.033333333,NA,0.019245009,3,30.46870825,NA,8.17441427,NA,0.8778,"growth rate (day-1)",2,NA,0.17521298,NA,0.102288626,3,0.8,0.126116414,-2.960227955,1.396912462
"3480",3480,3496,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,372.7326172,NA,100,NA,1.344444444,"growth rate (day-1)","biom","biom","dSS",NA,0.033333333,NA,0.019245009,3,79.29827374,NA,21.27484156,NA,1.4194,"growth rate (day-1)",2,NA,0.177169097,NA,0.059576696,3,0.8,0.127475488,0.470678724,0.685128205
"3481",3481,3497,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,372.7326172,NA,100,NA,1.344444444,"growth rate (day-1)","biom","biom","dSS",NA,0.033333333,NA,0.019245009,3,163.4199134,NA,43.84373835,NA,1.725,"growth rate (day-1)",2,NA,0.103189865,NA,0.073981424,3,0.8,0.076678743,3.970389087,1.980332458
"3482",3482,3498,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,372.7326172,NA,100,NA,1.344444444,"growth rate (day-1)","biom","biom","dSS",NA,0.033333333,NA,0.019245009,3,236.9729036,NA,63.57718448,NA,1.4667,"growth rate (day-1)",2,NA,0.128139584,NA,0.091023746,3,0.8,0.093623886,1.044367859,0.757558685
"3483",3483,3499,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,380.9701958,NA,100,NA,1.181481481,"growth rate (day-1)","biom","biom","dSS",NA,0.113492988,NA,0.065525207,3,29.24839221,NA,7.677343933,NA,1.3963,"growth rate (day-1)",2,NA,0.157657753,NA,0.173205081,3,0.8,0.137361977,1.251087495,0.79710166
"3484",3484,3500,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,380.9701958,NA,100,NA,1.181481481,"growth rate (day-1)","biom","biom","dSS",NA,0.113492988,NA,0.065525207,3,79.20474587,NA,20.79027356,NA,1.6667,"growth rate (day-1)",2,NA,0.3,NA,0.116593157,3,0.8,0.226804606,1.711376834,0.910734222
"3485",3485,3501,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,380.9701958,NA,100,NA,1.181481481,"growth rate (day-1)","biom","biom","dSS",NA,0.113492988,NA,0.065525207,3,165.3109579,NA,43.39209726,NA,2.1593,"growth rate (day-1)",2,NA,0.201945272,NA,0.058208273,3,0.8,0.163802551,4.77539707,2.567034765
"3486",3486,3502,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,380.9701958,NA,100,NA,1.181481481,"growth rate (day-1)","biom","biom","dSS",NA,0.113492988,NA,0.065525207,3,243.8708068,NA,64.01309329,NA,1.4963,"growth rate (day-1)",2,NA,0.100819686,NA,0.101159261,3,0.8,0.107343531,2.346222902,1.125396825
"3487",3487,3503,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,1.344444444,"Chl a (pg cell-1)","phys","phys","Q",NA,0.033333333,NA,0.019245009,3,30.59163059,NA,7.969924812,NA,0.8778,"Chl a (pg cell-1)",1,NA,0.17521298,NA,0.102288626,3,0.8,0.126116414,-2.960227955,1.396912462
"3488",3488,3504,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,1.344444444,"Chl a (pg cell-1)","phys","phys","Q",NA,0.033333333,NA,0.019245009,3,81.38528139,NA,21.20300752,NA,1.4194,"Chl a (pg cell-1)",1,NA,0.177169097,NA,0.059576696,3,0.8,0.127475488,0.470678724,0.685128205
"3489",3489,3505,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,1.344444444,"Chl a (pg cell-1)","phys","phys","Q",NA,0.033333333,NA,0.019245009,3,169.6969697,NA,44.21052632,NA,1.725,"Chl a (pg cell-1)",1,NA,0.103189865,NA,0.073981424,3,0.8,0.076678743,3.970389087,1.980332458
"3490",3490,3506,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,1.344444444,"Chl a (pg cell-1)","phys","phys","Q",NA,0.033333333,NA,0.019245009,3,245.3102453,NA,63.90977444,NA,1.4667,"Chl a (pg cell-1)",1,NA,0.128139584,NA,0.091023746,3,0.8,0.093623886,1.044367859,0.757558685
"3491",3491,3507,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,1.181481481,"Chl a (pg cell-1)","phys","phys","Q",NA,0.113492988,NA,0.065525207,3,32.03463203,NA,8.57805255,NA,1.3963,"Chl a (pg cell-1)",1,NA,0.157657753,NA,0.173205081,3,0.8,0.137361977,1.251087495,0.79710166
"3492",3492,3508,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,1.181481481,"Chl a (pg cell-1)","phys","phys","Q",NA,0.113492988,NA,0.065525207,3,81.38528139,NA,21.79289026,NA,1.6667,"Chl a (pg cell-1)",1,NA,0.3,NA,0.116593157,3,0.8,0.226804606,1.711376834,0.910734222
"3493",3493,3509,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,1.181481481,"Chl a (pg cell-1)","phys","phys","Q",NA,0.113492988,NA,0.065525207,3,164.9350649,NA,44.16537867,NA,2.1593,"Chl a (pg cell-1)",1,NA,0.201945272,NA,0.058208273,3,0.8,0.163802551,4.77539707,2.567034765
"3494",3494,3510,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,1.181481481,"Chl a (pg cell-1)","phys","phys","Q",NA,0.113492988,NA,0.065525207,3,243.2900433,NA,65.14683153,NA,1.4963,"Chl a (pg cell-1)",1,NA,0.100819686,NA,0.187515472,3,0.8,0.107343531,2.346222902,1.125396825
"3495",3495,3511,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,26.58476658,"cell volume (micrometer)","biom","biom","dSS",NA,0.667473106,NA,0.385365777,3,30.59163059,NA,7.969924812,NA,20.8907,"cell volume (micrometer)",2,NA,3.598669934,NA,2.077693055,3,0.8,2.588044208,-1.76012548,0.924836809
"3496",3496,3512,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,26.58476658,"cell volume (micrometer)","biom","biom","dSS",NA,0.667473106,NA,0.385365777,3,81.38528139,NA,21.20300752,NA,23.2494,"cell volume (micrometer)",2,NA,1.682329157,NA,0.971293192,3,0.8,1.279795245,-2.084946536,1.028916838
"3497",3497,3513,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,26.58476658,"cell volume (micrometer)","biom","biom","dSS",NA,0.667473106,NA,0.385365777,3,169.6969697,NA,44.21052632,NA,25.5344,"cell volume (micrometer)",2,NA,1.725902134,NA,0.996450062,3,0.8,1.308483573,-0.642189827,0.701033981
"3498",3498,3514,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,7.68,NA,35,NA,NA,NA,NA,NA,0,383.8383838,NA,100,NA,26.58476658,"cell volume (micrometer)","biom","biom","dSS",NA,0.667473106,NA,0.385365777,3,245.3102453,NA,63.90977444,NA,27.8747,"cell volume (micrometer)",2,NA,1.110554239,NA,0.641178789,3,0.8,0.916201688,1.126325181,0.772384035
"3499",3499,3515,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,28.86977887,"cell volume (micrometer)","biom","biom","dSS",NA,0.710834208,NA,0.410400321,3,32.03463203,NA,8.57805255,NA,17.887,"cell volume (micrometer)",2,NA,2.535240814,NA,1.267620407,4,0.842105263,2.014592192,-4.590842031,2.088749801
"3500",3500,3516,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,28.86977887,"cell volume (micrometer)","biom","biom","dSS",NA,0.710834208,NA,0.410400321,3,81.38528139,NA,21.79289026,NA,20.4423,"cell volume (micrometer)",2,NA,2.987153219,NA,1.49357661,4,0.842105263,2.357109399,-3.01083082,1.230840635
"3501",3501,3517,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,28.86977887,"cell volume (micrometer)","biom","biom","dSS",NA,0.710834208,NA,0.410400321,3,164.9350649,NA,44.16537867,NA,23.3661,"cell volume (micrometer)",2,NA,3.238493283,NA,1.619246642,4,0.842105263,2.548493154,-1.818597205,0.819568747
"3502",3502,3518,"S7","Li, G., and D. A. Campbell",2013,"Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana","PloS One",1,"Li, G., and D. A. Campbell (2013), Rising CO2 interacts with growth light and growth rate to alter photosystem II photoinactivation of the coastal diatom Thalassiosira pseudonana, PLoS One, 8 (1), e55562, doi:10.1371/journal.pone.0055562.",NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",6,"microcosm","culture flask",3.5,NA,"No","pCO2","light gradient",NA,NA,NA,18,8.02,NA,35,NA,NA,NA,NA,NA,0,373.4487734,NA,100,NA,28.86977887,"cell volume (micrometer)","biom","biom","dSS",NA,0.710834208,NA,0.410400321,3,243.2900433,NA,65.14683153,NA,24.6437,"cell volume (micrometer)",2,NA,3.106626756,NA,1.793611794,3,0.8,2.25348786,-1.500267849,0.854233635
"3503",3503,3519,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.528571429,"growth rate (day-1)","biom","biom","dSS",NA,0.205128205,NA,0.083743239,6,96,NA,9.655172414,NA,1.1311,"growth rate (day-1)",2,NA,0.324786325,NA,0.104679049,6,0.923076923,0.271628181,-1.350693605,0.409348884
"3504",3504,3520,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.528571429,"growth rate (day-1)","biom","biom","dSS",NA,0.205128205,NA,0.083743239,6,171.4285714,NA,17.24137931,NA,1.0446,"growth rate (day-1)",2,NA,0.256410256,NA,0.055868704,6,0.923076923,0.232189363,-1.924178327,0.487602593
"3505",3505,3521,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.528571429,"growth rate (day-1)","biom","biom","dSS",NA,0.205128205,NA,0.083743239,6,274.2857143,NA,27.5862069,NA,1.1286,"growth rate (day-1)",2,NA,0.136849817,NA,0.069786033,6,0.923076923,0.174363776,-2.11758874,0.520174253
"3506",3506,3522,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.528571429,"growth rate (day-1)","biom","biom","dSS",NA,0.205128205,NA,0.083743239,6,370.2857143,NA,37.24137931,NA,1.4178,"growth rate (day-1)",2,NA,0.170940171,NA,0.048890101,6,0.923076923,0.18880959,-0.541543047,0.34555287
"3507",3507,3523,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,994.2857143,NA,100,NA,0.93028083,"growth rate (day-1)","biom","biom","dSS",NA,0.256312576,NA,0.104639171,6,102.8571429,NA,10.34482759,NA,0.7037,"growth rate (day-1)",2,NA,0.1197558,NA,0.076764636,6,0.923076923,0.20004698,-1.0456828,0.378893855
"3508",3508,3524,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,994.2857143,NA,100,NA,0.93028083,"growth rate (day-1)","biom","biom","dSS",NA,0.256312576,NA,0.104639171,6,164.5714286,NA,16.55172414,NA,0.6173,"growth rate (day-1)",2,NA,0.188034188,NA,0.139572065,6,0.923076923,0.224780996,-1.285218281,0.402157751
"3509",3509,3525,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,994.2857143,NA,100,NA,0.93028083,"growth rate (day-1)","biom","biom","dSS",NA,0.256312576,NA,0.104639171,6,267.4285714,NA,26.89655172,NA,0.9235,"growth rate (day-1)",2,NA,0.341880342,NA,0.048810345,6,0.923076923,0.302140948,-0.020591287,0.333351
"3510",3510,3526,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,994.2857143,NA,100,NA,0.93028083,"growth rate (day-1)","biom","biom","dSS",NA,0.256312576,NA,0.104639171,6,363.4285714,NA,36.55172414,NA,0.7683,"growth rate (day-1)",2,NA,0.11956044,NA,0.139532187,6,0.923076923,0.199988544,-0.747520981,0.356616151
"3511",3511,3527,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,7.82,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.443101343,"growth rate (day-1)","biom","biom","dSS",NA,0.256410256,NA,0.104679049,6,102.8571429,NA,10.34482759,NA,1.1139,"growth rate (day-1)",2,NA,0.341782662,NA,0.062767552,6,0.923076923,0.302127132,-1.005736362,0.375479401
"3512",3512,3528,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,7.82,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.443101343,"growth rate (day-1)","biom","biom","dSS",NA,0.256410256,NA,0.104679049,6,164.5714286,NA,16.55172414,NA,1.1985,"growth rate (day-1)",2,NA,0.153748474,NA,0.125614859,6,0.923076923,0.211405786,-1.067975854,0.380857184
"3513",3513,3529,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,7.82,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.443101343,"growth rate (day-1)","biom","biom","dSS",NA,0.256410256,NA,0.104679049,6,267.4285714,NA,26.89655172,NA,1.5047,"growth rate (day-1)",2,NA,0.307692308,NA,0.055828826,6,0.923076923,0.283214385,0.200889866,0.335014864
"3514",3514,3530,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"295",20,7.82,NA,NA,5,50,NA,NA,NA,2,994.2857143,NA,100,NA,1.443101343,"growth rate (day-1)","biom","biom","dSS",NA,0.256410256,NA,0.104679049,6,370.2857143,NA,37.24137931,NA,1.6742,"growth rate (day-1)",2,NA,0.136752137,NA,0.048890101,6,0.923076923,0.205484022,1.038199133,0.37824406
"3515",3515,3531,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,1001.142857,NA,100,NA,0.742148962,"growth rate (day-1)","biom","biom","dSS",NA,0.222319902,NA,0.09076172,6,102.8571429,NA,10.2739726,NA,0.4473,"growth rate (day-1)",2,NA,0.1197558,NA,0.097700446,6,0.923076923,0.178560341,-1.524481246,0.430168461
"3516",3516,3532,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,1001.142857,NA,100,NA,0.742148962,"growth rate (day-1)","biom","biom","dSS",NA,0.222319902,NA,0.09076172,6,171.4285714,NA,17.12328767,NA,0.5147,"growth rate (day-1)",2,NA,0.239316239,NA,0.062847307,6,0.923076923,0.230974459,-0.909179237,0.367775287
"3517",3517,3533,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,1001.142857,NA,100,NA,0.742148962,"growth rate (day-1)","biom","biom","dSS",NA,0.222319902,NA,0.09076172,6,274.2857143,NA,27.39726027,NA,0.6499,"growth rate (day-1)",2,NA,0.153943834,NA,0.195400891,6,0.923076923,0.191213026,-0.445141923,0.341589639
"3518",3518,3534,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,1001.142857,NA,100,NA,0.742148962,"growth rate (day-1)","biom","biom","dSS",NA,0.222319902,NA,0.09076172,6,370.2857143,NA,36.98630137,NA,1.0417,"growth rate (day-1)",2,NA,0.478632479,NA,0.126697745,6,0.923076923,0.373172339,0.741051364,0.35621488
"3519",3519,3535,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.793103448,"growth rate (day-1)","biom","biom","dSS",NA,0.172413793,NA,0.070387636,6,89.14285714,NA,9.77443609,NA,0.3103,"growth rate (day-1)",2,NA,0.310344828,NA,0.070387636,6,0.923076923,0.251038272,-5.452157769,1.571917681
"3520",3520,3536,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.793103448,"growth rate (day-1)","biom","biom","dSS",NA,0.172413793,NA,0.070387636,6,150.8571429,NA,16.54135338,NA,0.1724,"growth rate (day-1)",2,NA,0.172413793,NA,0.056310109,6,0.923076923,0.172413793,-8.676923077,3.470374753
"3521",3521,3537,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.793103448,"growth rate (day-1)","biom","biom","dSS",NA,0.172413793,NA,0.070387636,6,246.8571429,NA,27.06766917,NA,0.1379,"growth rate (day-1)",2,NA,0.137931034,NA,0.112620218,6,0.923076923,0.15612733,-9.785932157,4.323519507
"3522",3522,3538,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.793103448,"growth rate (day-1)","biom","biom","dSS",NA,0.172413793,NA,0.070387636,6,336,NA,36.84210526,NA,0.2759,"growth rate (day-1)",2,NA,0.275862069,NA,0.070387636,6,0.923076923,0.230028691,-6.088503566,1.877911486
"3523",3523,3539,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.379310345,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,89.14285714,NA,9.701492537,NA,0.1724,"growth rate (day-1)",2,NA,0.172413793,NA,0.140775273,6,0.923076923,0.15612733,-7.135575531,2.45485159
"3524",3524,3540,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.37931,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,157.7142857,NA,17.1641791,NA,0.3448,"growth rate (day-1)",2,NA,0.344827586,NA,0.0774264,6,0.923076923,0.262612866,-3.636176929,0.884240944
"3525",3525,3541,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.37931,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,240,NA,26.11940299,NA,0.1897,"growth rate (day-1)",2,NA,0.189655172,NA,0.0774264,6,0.923076923,0.165822276,-6.622408893,2.160679148
"3526",3526,3542,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,8.2,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.37931,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,336,NA,36.56716418,NA,0.1897,"growth rate (day-1)",2,NA,0.189655172,NA,0.070387636,6,0.923076923,0.165822276,-6.622408893,2.160679148
"3527",3527,3543,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.551724138,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,89.14285714,NA,9.77443609,NA,0.1724,"growth rate (day-1)",2,NA,0.172413793,NA,0.084465164,6,0.923076923,0.15612733,-8.154943464,3.104295954
"3528",3528,3544,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.551724138,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,157.7142857,NA,17.29323308,NA,0.2069,"growth rate (day-1)",2,NA,0.206896552,NA,0.049271345,6,0.923076923,0.175828259,-7.060180865,2.41025641
"3529",3529,3545,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.551724138,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,246.8571429,NA,27.06766917,NA,0.1207,"growth rate (day-1)",2,NA,0.120689655,NA,0.133736509,6,0.923076923,0.129597383,-10.19275915,4.662180796
"3530",3530,3546,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,5,50,NA,NA,NA,2,912,NA,100,NA,1.551724138,"growth rate (day-1)","biom","biom","dSS",NA,0.137931034,NA,0.056310109,6,336,NA,36.84210526,NA,0.3276,"growth rate (day-1)",2,NA,0.327586207,NA,0.042232582,6,0.923076923,0.251334133,-4.495901371,1.175547047
"3531",3531,3547,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.034482759,"growth rate (day-1)","biom","biom","dSS",NA,0.103448276,NA,0.042232582,6,89.14285714,NA,9.701492537,NA,0.1034,"growth rate (day-1)",2,NA,0.103448276,NA,0.119658982,6,0.923076923,0.103448276,-8.307692308,3.209072978
"3532",3532,3548,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.034482759,"growth rate (day-1)","biom","biom","dSS",NA,0.103448276,NA,0.042232582,6,150.8571429,NA,16.41791045,NA,0.2931,"growth rate (day-1)",2,NA,0.293103448,NA,0.028155055,6,0.923076923,0.219785324,-3.113720792,0.737302382
"3533",3533,3549,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.034482759,"growth rate (day-1)","biom","biom","dSS",NA,0.103448276,NA,0.042232582,6,253.7142857,NA,27.6119403,NA,0.069,"growth rate (day-1)",2,NA,0.068965517,NA,0.028155055,6,0.923076923,0.08791413,-10.1376956,4.615536337
"3534",3534,3550,"S8","Li, W., Y. Yang, Z. Li, J. Xu, and K. Gao",2017,"Effects of seawater acidification on the growth rates of the diatom Thalassiosira (Conticribra) weissflogii under different nutrient, light, and UV radiation regimes","Journal of Applied Phycology",1,NA,NA,"Fig. 2",NA,NA,"lab","coastal",NA,NA,NA,"Thalassiosira weissflogii","phytoplankton",90,"microcosm","culture flask",1,NA,"No","nut_pCO2","light reduced","12",NA,"395",20,7.82,NA,NA,1.5,15,NA,NA,NA,2,918.8571429,NA,100,NA,1.034482759,"growth rate (day-1)","biom","biom","dSS",NA,0.103448276,NA,0.042232582,6,349.7142857,NA,38.05970149,NA,0.069,"growth rate (day-1)",2,NA,0.068965517,NA,0.06212474,6,0.923076923,0.08791413,-10.1376956,4.615536337
"3535",3535,3551,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,8.1,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,1.032608696,"specific growth rate (d-1)","biom","biom","dSS",NA,0.15217391,NA,0.087857648,3,50,NA,16.66666667,NA,0.6413,"specific growth rate (d-1)",2,NA,0.152173913,NA,0.08785765,3,0.8,0.152173912,-2.057142878,1.019319735
"3536",3536,3552,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,8.1,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,0.826086957,"specific growth rate (d-1)","biom","biom","dSS",NA,0.18478261,NA,0.10668429,3,50,NA,16.66666667,NA,0.75,"specific growth rate (d-1)",2,NA,0.163043478,NA,0.094133196,3,0.8,0.174252387,-0.349318401,0.676835279
"3537",3537,3553,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,7.8,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,1.195652174,"specific growth rate (d-1)","biom","biom","dSS",NA,0.18478261,NA,0.10668429,3,50,NA,16.66666667,NA,0.8804,"specific growth rate (d-1)",2,NA,0.130434783,NA,0.075306557,3,0.8,0.15993412,-1.576736178,0.873841415
"3538",3538,3554,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,7.8,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,0.869565217,"specific growth rate (d-1)","biom","biom","dSS",NA,0.13043478,NA,0.075306555,3,50,NA,16.66666667,NA,0.7609,"specific growth rate (d-1)",2,NA,0.130434783,NA,0.075306557,3,0.8,0.130434781,-0.666666673,0.703703704
"3539",3539,3555,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,8.1,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,10.95652174,"PIC production (pg cell-1)","biom","biom","dSS",NA,2.347826087,NA,1.355518023,3,50,NA,16.66666667,NA,4.6957,"POC production (pg cell-1)",2,NA,1.130434783,NA,0.652656826,3,0.8,1.842575661,-2.718312066,1.282435041
"3540",3540,3556,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,8.1,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,12.26086957,"PIC production (pg cell-1)","biom","biom","dSS",NA,3.304347826,NA,1.907766107,3,50,NA,16.66666667,NA,8.6957,"POC production (pg cell-1)",2,NA,2.086956522,NA,1.20490491,3,0.8,2.763521493,-1.032079512,0.755432343
"3541",3541,3557,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,7.8,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,11.39130435,"PIC production (pg cell-1)","biom","biom","dSS",NA,3.043478261,NA,1.757152993,3,50,NA,16.66666667,NA,6.6957,"POC production (pg cell-1)",2,NA,1.130434783,NA,0.652656826,3,0.8,2.295718049,-1.636316681,0.889794357
"3542",3542,3558,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,7.8,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,8.956521739,"PIC production (pg cell-1)","biom","biom","dSS",NA,1.739130435,NA,1.004087425,3,50,NA,16.66666667,NA,7.4783,"POC production (pg cell-1)",2,NA,2.173913043,NA,1.255109281,3,0.8,1.968561987,-0.600747502,0.696741463
"3543",3543,3559,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,8.1,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,0.123641304,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.027173913,NA,0.015688866,3,50,NA,16.66666667,NA,0.159,"Chl a (pg cell-1)",1,NA,0.013586957,NA,0.007844433,3,0.8,0.021482865,1.315507507,0.81088
"3544",3544,3560,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,8.1,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,0.100543478,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.023097826,NA,0.013335536,3,50,NA,16.66666667,NA,0.1821,"Chl a (pg cell-1)",1,NA,0.006793478,NA,0.003922217,3,0.8,0.017024408,3.830817045,1.889596603
"3545",3545,3561,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,7.8,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,0.089673913,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.016304348,NA,0.00941332,3,50,NA,16.66666667,NA,0.1834,"Chl a (pg cell-1)",1,NA,0.010869565,NA,0.006275546,3,0.8,0.013856031,5.41280533,3.108205128
"3546",3546,3562,"S9","Rokitta, S. D., and B. Rost",2012,"Effects of CO2 and their modulation by light in the life-cycle stages of the coccolithophore Emiliania huxleyi","Limnology and Oceanography",1,"diploid and haploid species",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Emiliania huxleyi","phytoplankton",6,"microcosm","culture flask",0.98,NA,"No","pCO2","light reduced","16",NA,NA,15,7.8,NA,32,6.25,100,NA,NA,NA,2,300,NA,100,NA,0.07201087,"Chl a (pg cell-1)","cellular content","phys","Q",NA,0.004076087,NA,0.00235333,3,50,NA,16.66666667,NA,0.1264,"Chl a (pg cell-1)",1,NA,0.013586957,NA,0.007844433,3,0.8,0.01003045,4.334626953,2.232415902
"3547",3547,3563,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Table 3",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,8.03,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,0.676,"Fv/Fm","productivity","phys","dQ",NA,0.01,NA,0.005773503,3,30,NA,12,NA,0.696,"Fv/Fm",1,NA,0,NA,0,3,0.8,0.007071068,2.2627417,1.093333333
"3548",3548,3564,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Table 3",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,7.83,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,0.666,"Fv/Fm","productivity","phys","dQ",NA,0,NA,0,3,30,NA,12,NA,0.686,"Fv/Fm",1,NA,0,NA,0,3,0.8,0,NA,NA
"3549",3549,3565,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Table 3",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,8.03,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,0.706,"Fv/Fm","productivity","phys","dQ",NA,0.02,NA,0.011547005,3,30,NA,12,NA,0.706,"Fv/Fm",1,NA,0.01,NA,0.005773503,3,0.8,0.015811388,0,0.666666667
"3550",3550,3566,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Table 3",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,7.82,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,0.696,"Fv/Fm","productivity","phys","dQ",NA,0.01,NA,0.005773503,3,30,NA,12,NA,0.696,"Fv/Fm",1,NA,0.01,NA,0.005773503,3,0.8,0.01,0,0.666666667
"3551",3551,3567,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,8.03,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,2.028571429,"growth rate (day-1)","biom","biom","dSS",NA,0.114285714,NA,0.065982888,3,30,NA,12,NA,0.9857,"growth rate (day-1)",2,NA,0.057142857,NA,0.032991444,3,0.8,0.09035079,-9.233850768,7.772
"3552",3552,3568,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,7.83,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,2.057142857,"growth rate (day-1)","biom","biom","dSS",NA,0.042857143,NA,0.024743583,3,30,NA,12,NA,1.0143,"growth rate (day-1)",2,NA,0.114285714,NA,0.065982888,3,0.8,0.086307471,-9.666436779,8.453333333
"3553",3553,3569,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,8.03,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,2.2,"growth rate (day-1)","biom","biom","dSS",NA,0.057142857,NA,0.032991444,3,30,NA,12,NA,1.4286,"growth rate (day-1)",2,NA,0.028571429,NA,0.016495722,3,0.8,0.045175395,-13.66103949,16.21866667
"3554",3554,3570,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,7.82,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,2.271428571,"growth rate (day-1)","biom","biom","dSS",NA,0.042857143,NA,0.024743583,3,30,NA,12,NA,1.4286,"growth rate (day-1)",2,NA,0.071428571,NA,0.041239305,3,0.8,0.058901509,-11.4476815,11.58745098
"3555",3555,3571,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,8.03,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,0.857142857,"Cellular C quota (pmol cell-1)","biom","biom","SS",NA,0.035714286,NA,0.020619652,3,30,NA,12,NA,0.6429,"Cellular C quota (pmol cell-1)",2,NA,0.021428571,NA,0.012371791,3,0.8,0.029450754,-5.820855001,3.490196078
"3556",3556,3572,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,7.83,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,0.857142857,"Cellular C quota (pmol cell-1)","biom","biom","SS",NA,0.042857143,NA,0.024743583,3,30,NA,12,NA,0.6357,"Cellular C quota (pmol cell-1)",2,NA,0.014285714,NA,0.008247861,3,0.8,0.031943828,-5.545448584,3.229333333
"3557",3557,3573,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,8.03,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,1.1,"Cellular C quota (pmol cell-1)","biom","biom","SS",NA,0.035714286,NA,0.020619652,3,30,NA,12,NA,0.7071,"Cellular C quota (pmol cell-1)",2,NA,0.035714286,NA,0.020619652,3,0.8,0.035714286,-8.8,7.12
"3558",3558,3574,"S10","Shi, D., W. Li, B. M. Hopkinson, H. Hong, D. Li, S.-J. Kao, and W. Lin",2015,"Interactive effects of light, nitrogen source, and carbon dioxide on energy metabolism in the diatom Thalassiosira pseudonana","Limnology and Oceanography",1,"No3- or NH4+ as nitrogen source",NA,"Fig. 1",NA,NA,"Lab","culture",NA,NA,NA,"Thalassiosira pseudonana","phytoplankton",60,"microcosm","culture flask",1,NA,"No","pCO2","light reduced","24",NA,NA,20,7.82,NA,NA,NA,100,NA,NA,NA,1,250,NA,100,NA,1.071428571,"Cellular C quota (pmol cell-1)","biom","biom","SS",NA,0.057142857,NA,0.032991444,3,30,NA,12,NA,0.7571,"Cellular C quota (pmol cell-1)",2,NA,0.028571429,NA,0.016495722,3,0.8,0.045175395,-5.565608682,3.248
"3559",3559,3575,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,36,"Chl a (pg cell-1)","cellular content","phys","Q",NA,5,NA,2.886751346,3,20,NA,10,NA,85,"Chl a (pg cell-1)",1,NA,1,NA,0.577350269,3,0.8,3.605551275,10.87212385,10.51692308
"3560",3560,3576,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,42,"Chl a (pg cell-1)","cellular content","phys","Q",NA,4,NA,2.309401077,3,20,NA,10,NA,83,"Chl a (pg cell-1)",1,NA,13,NA,7.505553499,3,0.8,9.617692031,3.410381607,1.635891892
"3561",3561,3577,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,21,"Chl a (pg cell-1)","cellular content","phys","Q",NA,6,NA,3.464101615,3,20,NA,10,NA,182,"Chl a (pg cell-1)",1,NA,48,NA,27.71281292,3,0.8,34.20526275,3.76550243,1.848250712
"3562",3562,3578,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,53,"Chl a (pg cell-1)","cellular content","phys","Q",NA,11,NA,6.350852961,3,20,NA,10,NA,139,"Chl a (pg cell-1)",1,NA,25,NA,14.43375673,3,0.8,19.31320792,3.562328967,1.724182306
"3563",3563,3579,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,200,"Chl a (pg cell-1)","cellular content","phys","Q",NA,2,NA,1.154700538,3,20,NA,10,NA,79,"Chl a (pg cell-1)",1,NA,7,NA,4.041451884,3,0.8,5.14781507,-18.8040943,30.13283019
"3564",3564,3580,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,55,"Chl a (pg cell-1)","cellular content","phys","Q",NA,3,NA,1.732050808,3,20,NA,10,NA,87,"Chl a (pg cell-1)",1,NA,4,NA,2.309401077,3,0.8,3.535533906,7.240773439,5.035733333
"3565",3565,3581,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,78,"ETRmax (e? PSII?1 s?1)","productivity","phys","dQ",NA,14,NA,8.082903769,3,20,NA,10,NA,15,"ETRmax (e? PSII?1 s?1)",1,NA,4,NA,2.309401077,3,0.8,10.29563014,-4.895280746,2.663647799
"3566",3566,3582,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,70,"ETRmax (e? PSII?1 s?1)","productivity","phys","dQ",NA,11,NA,6.350852961,3,20,NA,10,NA,18,"ETRmax (e? PSII?1 s?1)",1,NA,2,NA,1.154700538,3,0.8,7.90569415,-5.262030027,2.97408
"3567",3567,3583,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,167,"ETRmax (e? PSII?1 s?1)","productivity","phys","dQ",NA,4,NA,2.309401077,3,20,NA,10,NA,94,"ETRmax (e? PSII?1 s?1)",1,NA,15,NA,8.660254038,3,0.8,10.9772492,-5.320094218,3.025283541
"3568",3568,3584,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,118,"ETRmax (e? PSII?1 s?1)","productivity","phys","dQ",NA,29,NA,16.74315781,3,20,NA,10,NA,51,"ETRmax (e? PSII?1 s?1)",1,NA,9,NA,5.196152423,3,0.8,21.47091055,-2.49640088,1.186001446
"3569",3569,3585,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,412,"ETRmax (e? PSII?1 s?1)","productivity","phys","dQ",NA,22,NA,12.70170592,3,20,NA,10,NA,151,"ETRmax (e? PSII?1 s?1)",1,NA,12,NA,6.92820323,3,0.8,17.72004515,-11.78326569,12.23711253
"3570",3570,3586,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Table 3",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,72,"ETRmax (e? PSII?1 s?1)","productivity","phys","dQ",NA,2,NA,1.154700538,3,20,NA,10,NA,134,"ETRmax (e? PSII?1 s?1)",1,NA,8,NA,4.618802154,3,0.8,5.830951895,8.506329823,6.696470588
"3571",3571,3587,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 2",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.427338129,"Fv/Fm","productivity","phys","dQ",NA,0.01294964,NA,0.007476478,3,20,NA,10,NA,0.4273,"Fv/Fm",1,NA,0.017266187,NA,0.009968638,3,0.8,0.015261297,0,0.666666667
"3572",3572,3588,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 2",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.418705036,"Fv/Fm","productivity","phys","dQ",NA,0.01294964,NA,0.007476478,3,20,NA,10,NA,0.4317,"Fv/Fm",1,NA,0.021582734,NA,0.012460797,3,0.8,0.017797578,0.582085487,0.69490196
"3573",3573,3589,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 2",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.487769784,"Fv/Fm","productivity","phys","dQ",NA,0.017266187,NA,0.009968638,3,20,NA,10,NA,0.5353,"Fv/Fm",1,NA,0.01294964,NA,0.007476478,3,0.8,0.015261297,2.489015926,1.182933357
"3574",3574,3590,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 2",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.435971223,"Fv/Fm","productivity","phys","dQ",NA,0.038848921,NA,0.022429435,3,20,NA,10,NA,0.5353,"Fv/Fm",1,NA,0.038848921,NA,0.022429435,3,0.8,0.038848921,2.044444447,1.014979425
"3575",3575,3591,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 2",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.535251799,"Fv/Fm","productivity","phys","dQ",NA,0.008633094,NA,0.004984319,3,20,NA,10,NA,0.5568,"Fv/Fm",1,NA,0.030215827,NA,0.017445116,3,0.8,0.022220784,0.777028665,0.716981129
"3576",3576,3592,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 2",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.44028777,"Fv/Fm","productivity","phys","dQ",NA,0.034532374,NA,0.019937275,3,20,NA,10,NA,0.5612,"Fv/Fm",1,NA,0.034532374,NA,0.019937275,3,0.8,0.034532374,2.8,1.32
"3577",3577,3593,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.452991453,"growth rate (day-1)","biom","biom","dSS",NA,0.075213675,NA,0.043424636,3,20,NA,10,NA,0.4051,"growth rate (day-1)",2,NA,0.068376068,NA,0.039476941,3,0.8,0.071876226,-0.532729673,0.690316742
"3578",3578,3594,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.48034188,"growth rate (day-1)","biom","biom","dSS",NA,0.041025641,NA,0.023686165,3,20,NA,10,NA,0.3231,"growth rate (day-1)",2,NA,0.068376068,NA,0.039476941,3,0.8,0.05638435,-2.23132775,1.081568627
"3579",3579,3595,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.876923077,"growth rate (day-1)","biom","biom","dSS",NA,0.095726496,NA,0.055267718,3,20,NA,10,NA,0.412,"growth rate (day-1)",2,NA,0.068376068,NA,0.039476941,3,0.8,0.083183077,-4.471652455,2.332972973
"3580",3580,3596,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,0.733333333,"growth rate (day-1)","biom","biom","dSS",NA,0.088888889,NA,0.051320024,3,20,NA,10,NA,0.3162,"growth rate (day-1)",2,NA,0.075213675,NA,0.043424636,3,0.8,0.082335689,-4.052619417,2.035310345
"3581",3581,3597,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,NA,"growth rate (day-1)","biom","biom","dSS",NA,NA,NA,NA,3,20,NA,10,NA,0.2,"growth rate (day-1)",2,NA,0.068376068,NA,0.039476941,3,0.8,NA,NA,NA
"3582",3582,3598,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,NA,"growth rate (day-1)","biom","biom","dSS",NA,NA,NA,NA,3,20,NA,10,NA,0.1932,"growth rate (day-1)",2,NA,0.054700855,NA,0.031581553,3,0.8,NA,NA,NA
"3583",3583,3599,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,5.294117647,"POC (pg cell-1)","biom","biom","SS",NA,0.588235294,NA,0.339617805,3,20,NA,10,NA,4.7059,"POC (pg cell-1)",2,NA,0.588235294,NA,0.339617805,3,0.8,0.588235294,-0.8,0.72
"3584",3584,3600,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",63.65,72.35,NA,"Phaeocystis antarctica","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,5,"POC (pg cell-1)","biom","biom","SS",NA,0.882352941,NA,0.509426708,3,20,NA,10,NA,4.7059,"POC (pg cell-1)",2,NA,0.588235294,NA,0.339617805,3,0.8,0.749855811,-0.313785816,0.674871795
"3585",3585,3601,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,33.23529412,"POC (pg cell-1)","biom","biom","SS",NA,3.529411765,NA,2.037706832,3,20,NA,10,NA,31.1765,"POC (pg cell-1)",2,NA,4.705882353,NA,2.716942443,3,0.8,4.159451654,-0.395979797,0.679733333
"3586",3586,3602,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-49.6,2.083333333,NA,"Chaetoceros debilis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,31.76470588,"POC (pg cell-1)","biom","biom","SS",NA,2.941176471,NA,1.698089027,3,20,NA,10,NA,27.0588,"POC (pg cell-1)",2,NA,3.235294118,NA,1.86789793,3,0.8,3.091734712,-1.217667825,0.790226244
"3587",3587,3603,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,8.17,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,40.29411765,"POC (pg cell-1)","biom","biom","SS",NA,2.941176471,NA,1.698089027,3,20,NA,10,NA,8.5294,"POC (pg cell-1)",2,NA,0.882352941,NA,0.509426708,3,0.8,2.171297509,-11.70349277,12.08097859
"3588",3588,3604,"S11","Trimborn, S., S. Thoms, T. Brenneis, J. P. Heiden, S. Beszteri, and K. Bischof",2017,"Two Southern Ocean diatoms are more sensitive to ocean acidification and changes in irradiance than the prymnesiophyte Phaeocystis antarctica","Physiologia Plantarum",1,"ambient and hi pco2",NA,"Fig. 1",NA,NA,"Lab","antarctica",-64,0,NA,"Fragilariopsis kerguelensis","phytoplankton",NA,"microcosm","culture flask",NA,NA,"No","pCO2","light reduced","16",NA,NA,2,7.83,NA,NA,6.25,100,NA,NA,NA,2,200,NA,100,NA,16.47058824,"POC (pg cell-1)","biom","biom","SS",NA,1.470588235,NA,0.849044514,3,20,NA,10,NA,7.9412,"POC (pg cell-1)",2,NA,0.882352941,NA,0.509426708,3,0.8,1.212678125,-5.626826501,3.305098039
"3589",3589,3605,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,1.26,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,50,NA,6.25,NA,0.5,"growth rate (day-1)",2,NA,0.002,NA,0.001,4,0.869565217,0.005147815,-128.3786531,1030.567411
"3590",3590,3606,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,1.26,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,100,NA,12.5,NA,0.72,"growth rate (day-1)",2,NA,0.003,NA,0.0015,4,0.869565217,0.005385165,-87.19607184,475.697184
"3591",3591,3607,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,1.26,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,200,NA,25,NA,1.09,"growth rate (day-1)",2,NA,0.011,NA,0.0055,4,0.869565217,0.009219544,-16.03399036,16.56805293
"3592",3592,3608,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,1.26,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,400,NA,50,NA,1.19,"growth rate (day-1)",2,NA,0.013,NA,0.0065,4,0.869565217,0.010440307,-5.830246954,2.624486221
"3593",3593,3609,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,1.26,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,600,NA,75,NA,1.21,"growth rate (day-1)",2,NA,0.006,NA,0.003,4,0.869565217,0.006519202,-6.669260773,3.279939953
"3594",3594,3610,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.88,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,50,NA,6.25,NA,0.52,"growth rate (day-1)",2,NA,0.007,NA,0.0035,4,0.869565217,0.007,-44.72049689,125.4951777
"3595",3595,3611,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.88,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,100,NA,12.5,NA,0.78,"growth rate (day-1)",2,NA,0.004,NA,0.002,4,0.869565217,0.005700877,-15.25318294,15.04122437
"3596",3596,3612,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.88,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,200,NA,25,NA,0.9,"growth rate (day-1)",2,NA,0.01,NA,0.005,4,0.869565217,0.008631338,2.014902422,0.753739486
"3597",3597,3613,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.88,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,400,NA,50,NA,0.95,"growth rate (day-1)",2,NA,0.007,NA,0.0035,4,0.869565217,0.007,8.695652174,5.225897921
"3598",3598,3614,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.88,"growth rate (day-1)","biom","biom","dSS",NA,0.007,NA,0.0035,4,600,NA,75,NA,0.89,"growth rate (day-1)",2,NA,0.008,NA,0.004,4,0.869565217,0.007516648,1.156852357,0.583644211
"3599",3599,3615,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.69,"growth rate (day-1)","biom","biom","dSS",NA,0.004,NA,0.002,4,50,NA,6.25,NA,0.5,"growth rate (day-1)",2,NA,0.016,NA,0.008,4,0.869565217,0.011661904,-14.16727442,13.04447904
"3600",3600,3616,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.69,"growth rate (day-1)","biom","biom","dSS",NA,0.004,NA,0.002,4,100,NA,12.5,NA,0.64,"growth rate (day-1)",2,NA,0.008,NA,0.004,4,0.869565217,0.006324555,-6.874516653,3.4536862
"3601",3601,3617,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.69,"growth rate (day-1)","biom","biom","dSS",NA,0.004,NA,0.002,4,200,NA,25,NA,0.7,"growth rate (day-1)",2,NA,0.007,NA,0.0035,4,0.869565217,0.005700877,1.525318294,0.645412244
"3602",3602,3618,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.69,"growth rate (day-1)","biom","biom","dSS",NA,0.004,NA,0.002,4,400,NA,50,NA,0.72,"growth rate (day-1)",2,NA,0.006,NA,0.003,4,0.869565217,0.00509902,5.116073091,2.135887742
"3603",3603,3619,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,0.69,"growth rate (day-1)","biom","biom","dSS",NA,0.004,NA,0.002,4,600,NA,75,NA,0.69,"growth rate (day-1)",2,NA,0.006,NA,0.003,4,0.869565217,0.00509902,0,0.5
"3604",3604,3620,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,29.47,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,0.233,NA,0.1165,4,50,NA,6.25,NA,0.229,"POC production rate (pg cell-1 day-1)",2,NA,10.79,NA,5.395,4,0.869565217,7.631460837,-3.331859662,1.19383055
"3605",3605,3621,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,29.47,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,0.233,NA,0.1165,4,100,NA,12.5,NA,0.67,"POC production rate (pg cell-1 day-1)",2,NA,23.8,NA,11.9,4,0.869565217,16.82994785,-1.488030652,0.638389701
"3606",3606,3622,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,29.47,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,0.233,NA,0.1165,4,200,NA,25,NA,0.343,"POC production rate (pg cell-1 day-1)",2,NA,33.8,NA,16.9,4,0.869565217,23.90077707,-1.059707223,0.570186212
"3607",3607,3623,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,29.47,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,0.233,NA,0.1165,4,400,NA,50,NA,2.514,"POC production rate (pg cell-1 day-1)",2,NA,46.58,NA,23.29,4,0.869565217,32.93744593,-0.711652022,0.531653038
"3608",3608,3624,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,29.47,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,0.233,NA,0.1165,4,600,NA,75,NA,1.028,"POC production rate (pg cell-1 day-1)",2,NA,52.69,NA,26.345,4,0.869565217,37.25782058,-0.663811611,0.527540366
"3609",3609,3625,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,19.89,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,1.391,NA,0.6955,4,50,NA,6.25,NA,0.098,"POC production rate (pg cell-1 day-1)",2,NA,6.96,NA,3.48,4,0.869565217,5.018788748,-3.429200878,1.234963666
"3610",3610,3626,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,19.89,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,1.391,NA,0.6955,4,100,NA,12.5,NA,0.722,"POC production rate (pg cell-1 day-1)",2,NA,17.27,NA,8.635,4,0.869565217,12.25128118,-1.360496575,0.615684433
"3611",3611,3627,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,19.89,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,1.391,NA,0.6955,4,200,NA,25,NA,3.484,"POC production rate (pg cell-1 day-1)",2,NA,19.19,NA,9.595,4,0.869565217,13.60498036,-1.048592985,0.568721703
"3612",3612,3628,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,19.89,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,1.391,NA,0.6955,4,400,NA,50,NA,4.087,"POC production rate (pg cell-1 day-1)",2,NA,18.71,NA,9.355,4,0.869565217,13.26647996,-1.03582406,0.567058218
"3613",3613,3629,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,19.89,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,1.391,NA,0.6955,4,600,NA,75,NA,1.988,"POC production rate (pg cell-1 day-1)",2,NA,23.35,NA,11.675,4,0.869565217,16.54021434,-0.941158089,0.555361159
"3614",3614,3630,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,14.92,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,2.454,NA,1.227,4,50,NA,6.25,NA,0.077,"POC production rate (pg cell-1 day-1)",2,NA,5.55,NA,2.775,4,0.869565217,4.290956537,-3.007943896,1.065482905
"3615",3615,3631,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,14.92,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,2.454,NA,1.227,4,100,NA,12.5,NA,1.106,"POC production rate (pg cell-1 day-1)",2,NA,7.03,NA,3.515,4,0.869565217,5.265121841,-2.281461717,0.825316723
"3616",3616,3632,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,14.92,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,2.454,NA,1.227,4,200,NA,25,NA,2.054,"POC production rate (pg cell-1 day-1)",2,NA,8.13,NA,4.065,4,0.869565217,6.004956952,-1.863098466,0.716945993
"3617",3617,3633,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,14.92,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,2.454,NA,1.227,4,400,NA,50,NA,0.938,"POC production rate (pg cell-1 day-1)",2,NA,14.01,NA,7.005,4,0.869565217,10.05739072,-1.208888191,0.591338166
"3618",3618,3634,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,14.92,"POC production rate (pg cell-1 day-1)","biom","biom","dSS",NA,2.454,NA,1.227,4,600,NA,75,NA,1.468,"POC production rate (pg cell-1 day-1)",2,NA,10.33,NA,5.165,4,0.869565217,7.507696584,-1.558053282,0.651720627
"3619",3619,3635,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,157,"rETRmax","productivity","phys","dQ",NA,2,NA,1,4,50,NA,6.25,NA,95,"rETRmax",1,NA,2,NA,1,4,0.869565217,2,-26.95652174,45.91587902
"3620",3620,3636,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,157,"rETRmax","productivity","phys","dQ",NA,2,NA,1,4,100,NA,12.5,NA,111,"rETRmax",1,NA,3,NA,1.5,4,0.869565217,2.549509757,-15.68929081,15.88461538
"3621",3621,3637,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,157,"rETRmax","productivity","phys","dQ",NA,2,NA,1,4,200,NA,25,NA,117,"rETRmax",1,NA,2,NA,1,4,0.869565217,2,-17.39130435,19.40359168
"3622",3622,3638,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,157,"rETRmax","productivity","phys","dQ",NA,2,NA,1,4,400,NA,50,NA,143,"rETRmax",1,NA,2,NA,1,4,0.869565217,2,-6.086956522,2.815689981
"3623",3623,3639,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,157,"rETRmax","productivity","phys","dQ",NA,2,NA,1,4,600,NA,75,NA,154,"rETRmax",1,NA,3,NA,1.5,4,0.869565217,2.549509757,-1.023214618,0.56543551
"3624",3624,3640,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,155,"rETRmax","productivity","phys","dQ",NA,17,NA,8.5,4,50,NA,6.25,NA,92,"rETRmax",1,NA,1,NA,0.5,4,0.869565217,12.04159458,-4.549448027,1.793592334
"3625",3625,3641,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,155,"rETRmax","productivity","phys","dQ",NA,17,NA,8.5,4,100,NA,12.5,NA,101,"rETRmax",1,NA,2,NA,1,4,0.869565217,12.10371844,-3.879512068,1.440663368
"3626",3626,3642,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,155,"rETRmax","productivity","phys","dQ",NA,17,NA,8.5,4,200,NA,25,NA,126,"rETRmax",1,NA,2,NA,1,4,0.869565217,12.10371844,-2.083441666,0.771295573
"3627",3627,3643,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,155,"rETRmax","productivity","phys","dQ",NA,17,NA,8.5,4,400,NA,50,NA,157,"rETRmax",1,NA,3,NA,1.5,4,0.869565217,12.20655562,0.142475117,0.501268697
"3628",3628,3644,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.69,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,155,"rETRmax","productivity","phys","dQ",NA,17,NA,8.5,4,600,NA,75,NA,180,"rETRmax",1,NA,10,NA,5,4,0.869565217,13.94632568,1.558771173,0.651860473
"3629",3629,3645,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,130,"rETRmax","productivity","phys","dQ",NA,11,NA,5.5,4,50,NA,6.25,NA,84,"rETRmax",1,NA,4,NA,2,4,0.869565217,8.276472679,-4.832976747,1.959854015
"3630",3630,3646,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,130,"rETRmax","productivity","phys","dQ",NA,11,NA,5.5,4,100,NA,12.5,NA,112,"rETRmax",1,NA,2,NA,1,4,0.869565217,7.90569415,-1.979860796,0.744990548
"3631",3631,3647,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,130,"rETRmax","productivity","phys","dQ",NA,11,NA,5.5,4,200,NA,25,NA,130,"rETRmax",1,NA,3,NA,1.5,4,0.869565217,8.062257748,0,0.5
"3632",3632,3648,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,130,"rETRmax","productivity","phys","dQ",NA,11,NA,5.5,4,400,NA,50,NA,171,"rETRmax",1,NA,10,NA,5,4,0.869565217,10.51189802,3.391601958,1.21893524
"3633",3633,3649,"S12","Zhang, Y., L. T. Bach, K. G. Schulz, and U. Riebesell",2015,"The modulating effect of light intensity on the response of the coccolithophore Gephyrocapsa oceanica to ocean acidification","Limnology and Oceanography",1,"pco2 and light levels",NA,"Table 3",NA,NA,"Lab","coastal",NA,NA,NA,"Gephyrocapsa oceanica","phytoplankton",9,"microcosm","batch",2,NA,"No","pCO2","light gradient","16",NA,NA,20,7.54,NA,35,4,64,NA,NA,NA,2,800,NA,100,NA,130,"rETRmax","productivity","phys","dQ",NA,11,NA,5.5,4,600,NA,75,NA,153,"rETRmax",1,NA,7,NA,3.5,4,0.869565217,9.219544457,2.169304578,0.794117647