Study,Authors,Year (online),Year (print),Title,Journal,Pub year IF,2017 IF,Species,Climate (FishBase),Env cue/stimulus?,Cue/stimulus type,Behavioural metric,Life stage,|lnRR|,Raw RR,OA as Percent of Control,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Habitat,% time in Xanthostemon cue,Larvae,0.2571,1.2932,77.329,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Habitat,% time in Melaleuca cue,Larvae,4.6702,106.7191,0.937,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Habitat,% time in Grass cue,Larvae,0.4318,1.54,64.934,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Habitat,% time in anemone cue,Larvae,0.1131,1.1197,89.306,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Kin,% time in Parent vs Seawater cue,Larvae,4.6955,109.4535,0.914,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Kin,% time in Non-parent vs Seawater cue,Larvae,0.0939,1.0984,91.037,
a1,Munday et al,2009,2009,Ocean acidification impairs olfactory discrimination and homing ability of marine fish.,PNAS,9.432,9.504,Amphiprion percula,Trop,Yes,Kin,% time in Non-parent vs Parent cue,Larvae,0.6633,1.9412,51.515,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, newly hatched, untreat vs.  pred 1",Larvae,0.1951,1.2154,82.275,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, newly hatched, untreat vs. pred 2",Larvae,0.0502,1.0515,95.104,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in non-predator cue, newly hatched, untreat vs.  Non-pred 1",Larvae,0.0323,1.0328,96.822,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in non-predator cue, newly hatched, untreat vs.  Non-pred 2",Larvae,2.0848,8.043,12.433,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, newly hatched, pred 1 vs. non-pred 1",Larvae,0,1,100,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, newly hatched, non-pred 2 vs. pred 2",Larvae,0.1627,1.1767,84.985,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, settlement stg, untreat vs.  pred 1",Larvae,13.8155,999989.4421,0,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, settlement stg, untreat vs. pred 2",Larvae,13.8155,999989.4421,0,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in non-predator cue, settlement stg, untreat vs. non-pred 1",Larvae,0.6878,1.9893,50.268,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in non-predator cue, settlement stg, untreat vs. non-pred 2",Larvae,0.6771,1.9682,50.809,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, settlement stg, pred 1 vs. non-pred 1",Larvae,13.1064,492081.681,0,
a2,Dixson et al,2009,2010,Ocean acidification disrupts the innate ability of fish to detect predator olfactory cues,Ecol Lett,10.318,9.137,Amphiprion percula,Trop,Yes,Predator,"% time in predator cue, settlement stg, non-pred 2 vs. pred 2",Larvae,13.1064,492081.681,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 1 dph, 550ppm (Fig 1)",Larvae,0.1867,1.2053,82.969,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 1 dph, 700ppm (Fig 1)",Larvae,0.1752,1.1915,83.929, 
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 1 dph, 850ppm (Fig 1)",Larvae,0.4403,1.5532,64.384,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 2 dph, 550ppm (Fig 1)",Larvae,0.0833,1.0869,92.008,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 2 dph, 700ppm (Fig 1)",Larvae,0.2822,1.326,75.412,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 2 dph, 850ppm (Fig 1)",Larvae,1.9613,7.1086,14.068,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 3 dph, 550ppm (Fig 1)",Larvae,0.0646,1.0667,93.744,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 3 dph, 700ppm (Fig 1)",Larvae,0.6593,1.9334,51.721,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 3 dph, 850ppm (Fig 1)",Larvae,1.9864,7.2892,13.719,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 4 dph, 550ppm (Fig 1)",Larvae,0.1911,1.2106,82.605,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 4 dph, 700ppm (Fig 1)",Larvae,1.5215,4.5791,21.838,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 4 dph, 850ppm (Fig 1)",Larvae,2.2118,9.1321,10.95,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 5 dph, 550ppm (Fig 1)",Larvae,0.066,1.0682,93.613,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 5 dph, 700ppm (Fig 1)",Larvae,0.9456,2.5744,38.845,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 5 dph, 850ppm (Fig 1)",Larvae,1.9963,7.3618,13.584,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 6 dph, 550ppm (Fig 1)",Larvae,0.0822,1.0857,92.109,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 6 dph, 700ppm (Fig 1)",Larvae,1.4623,4.3159,23.17,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 6 dph, 850ppm (Fig 1)",Larvae,2.2031,9.053,11.046,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 8 dph, 550ppm (Fig 1)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 8 dph, 700ppm (Fig 1)",Larvae,12.9841,435434.6471,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 8 dph, 850ppm (Fig 1)",Larvae,13.8002,984806.0527,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 10 dph, 550ppm (Fig 1)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 10 dph, 700ppm (Fig 1)",Larvae,13.0022,443387.7729,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 10 dph,850ppm (Fig 1)",Larvae,13.7508,937338.7293,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 1, 550ppm (Fig 2a)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 1, 700ppm (Fig 2a)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 1, 850ppm (Fig 2a)",Larvae,8.6359,5630.1986,0.018,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 2, 550ppm (Fig 2a)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 2, 700ppm (Fig 2a)",Larvae,11.2015,73240.2198,0.001,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 2, 850ppm (Fig 2a)",Larvae,13.5853,794366.3247,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 3, 550ppm (Fig 2a)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 3, 700ppm (Fig 2a)",Larvae,11.7276,123945.8431,0.001,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 3, 850ppm (Fig 2a)",Larvae,13.6702,864753.6953,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 4, 550ppm (Fig 2a)",Larvae,0,1,100,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 4, 700ppm (Fig 2a)",Larvae,13.0854,481855.7142,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Amphiprion percula,Trop,Yes,Predator,"% time in cue, day 4, 850ppm (Fig 2a)",Larvae,13.7003,891178.4794,0,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 1, 550ppm (Fig 2b)",Larvae,0.6931,1.9999,50.002,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 1, 700ppm (Fig 2b)",Larvae,0.3566,1.4285,70.005,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 1, 850ppm (Fig 2b)",Larvae,0.1543,1.1668,85.701,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 2, 550ppm (Fig 2b)",Larvae,0.4923,1.6361,61.122,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 2, 700ppm (Fig 2b)",Larvae,0.4923,1.6361,61.122,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 2, 850ppm (Fig 2b)",Larvae,3.319,27.6327,3.619,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 3, 550ppm (Fig 2b)",Larvae,1.1895,3.2854,30.437,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 3, 700ppm (Fig 2b)",Larvae,3.4657,31.9989,3.125,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 3, 850ppm (Fig 2b)",Larvae,3.8409,46.5674,2.147,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 4, 550ppm (Fig 2b)",Larvae,0.9025,2.4658,40.555,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 4, 700ppm (Fig 2b)",Larvae,3.3556,28.6628,3.489,
a3,Munday et al,2010,2010,Replenishment of fish populations is threatened by ocean acidification,PNAS,9.771,9.504,Pomacentrus wardi,Trop,Yes,Predator,"% time in cue, day 4, 850ppm (Fig 2b)",Larvae,4.0103,55.1634,1.813,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,Yes,Predator,"Prop time in prey cue, mid CO2",Adult,0.3937,1.4825,67.456,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,Yes,Predator,"Prop time in prey cue, high CO2",Adult,0.3591,1.432,69.83,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Line crosses, mid CO2",Adult,0.0241,1.0244,97.619,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Line crosses, high CO2",Adult,0.6559,1.9269,51.897,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Response time, mid CO2",Adult,0.8883,2.431,41.135,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Response time, high CO2",Adult,0.4829,1.6208,61.699,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Distance from shelter, mid CO2",Adult,0.2397,1.2709,78.686,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Distance from shelter, high CO2",Adult,0.5046,1.6563,60.375,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Feeding strikes, mid CO2",Adult,0.9556,2.6002,38.458,
a4,Cripps et al,2011,2011,Ocean Acidification Affects Prey Detection by a Predatory Reef Fish,PLoS One,4.092,2.766,Pseudochromis fuscus,Trop,No,null,"Feeding strikes, high CO2",Adult,0.0139,1.014,98.62,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus moluccensis,Trop,Yes,Prey,"Prey selectivity, small recruits",Adult,0.26,1.2969,77.105,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus amboinensis,Trop,Yes,Prey,"Prey selectivity, small recruits",Adult,0.2552,1.2907,77.476,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus nagasakiensis,Trop,Yes,Prey,"Prey selectivity, small recruits",Adult,0.4217,1.5246,65.593,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus chrysurus,Trop,Yes,Prey,"Prey selectivity, small recruits",Adult,0.3054,1.3572,73.683,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus moluccensis,Trop,Yes,Prey,"Prey selectivity, large recruits",Adult,1.6883,5.4103,18.483,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus amboinensis,Trop,Yes,Prey,"Prey selectivity, large recruits",Adult,0.5358,1.7088,58.52,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus nagasakiensis,Trop,Yes,Prey,"Prey selectivity, large recruits",Adult,1.2518,3.4966,28.599,
a5,Ferrari et al,2011,2011,Putting prey and predator into the CO 2 equation – qualitative and quantitative effects of ocean acidification on predator–prey interactions,Ecol Lett,17.557,9.137,Pomacentrus chrysurus,Trop,Yes,Prey,"Prey selectivity, large recruits",Adult,0.9089,2.4816,40.297,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus nagasakiensis,Trop,Yes,Predator,"Prop change in response, 700 ppm",Juvenile,0.3643,1.4395,69.468,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus nagasakiensis,Trop,Yes,Predator,"Prop change in response, 850 ppm",Juvenile,0.5528,1.7381,57.534,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus moluccensis,Trop,Yes,Predator,"Prop change in response, 700 ppm",Juvenile,0.8073,2.2418,44.606,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus moluccensis,Trop,Yes,Predator,"Prop change in response, 850 ppm",Juvenile,NA,NA,NA,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus chrysurus,Trop,Yes,Predator,"Prop change in response, 700 ppm",Juvenile,0.8139,2.2567,44.313,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus chrysurus,Trop,Yes,Predator,"Prop change in response, 850 ppm",Juvenile,NA,NA,NA,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus amboinensis,Trop,Yes,Predator,"Prop change in response, 700 ppm",Juvenile,3.1641,23.6674,4.225,
a6,Ferrari et al ,2011,2011,Intrageneric variation in antipredator responses of coral reef fishes affected by ocean acidification: implications for climate change projections on marine communities,Glob Change Biol,6.862,8.997,Pomacentrus amboinensis,Trop,Yes,Predator,"Prop change in response, 850 ppm",Juvenile,NA,NA,NA,
a7,Simpson et al,2011,2011,Ocean acidification erodes crucial auditory behaviour in a marine fish,Biol Lett,3.762,3.345,Amphiprion percula,Trop,Yes,Auditory,"% time at speaker (or 'in cue'), 600 uatm",Juvenile,0.7529,2.1231,47.1,
a7,Simpson et al,2011,2011,Ocean acidification erodes crucial auditory behaviour in a marine fish,Biol Lett,3.762,3.345,Amphiprion percula,Trop,Yes,Auditory,"% time at speaker (or 'in cue'), 700 uatm",Juvenile,0.8488,2.3368,42.793,
a7,Simpson et al,2011,2011,Ocean acidification erodes crucial auditory behaviour in a marine fish,Biol Lett,3.762,3.345,Amphiprion percula,Trop,Yes,Auditory,"% time at speaker (or 'in cue'), 900 uatm",Juvenile,0.7799,2.1813,45.845,
a8,Devine et al,2011,2012,Homing ability of adult cardinalfish is affected by elevated carbon dioxide,Oecologia,3.412,3.127,Cheilodipterus quinquelineatus,Trop,Yes,Habitat,"% time in homing cue, 550 ppm",Adult,0.5062,1.659,60.278,
a8,Devine et al,2011,2012,Homing ability of adult cardinalfish is affected by elevated carbon dioxide,Oecologia,3.412,3.127,Cheilodipterus quinquelineatus,Trop,Yes,Habitat,"% time in homing cue, 700 ppm",Adult,0.5062,1.659,60.278,
a8,Devine et al,2011,2012,Homing ability of adult cardinalfish is affected by elevated carbon dioxide,Oecologia,3.412,3.127,Cheilodipterus quinquelineatus,Trop,Yes,Habitat,"% time in homing cue, 960 ppm",Adult,0.3892,1.4758,67.76,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus moluccensis,Trop,Yes,Habitat,"% time in hard coral cue, hard vs. soft coral, 700 ppm",Larvae,0.179,1.196,83.611,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus moluccensis,Trop,Yes,Habitat,"% time in hard coral cue, hard vs. soft coral, 850 ppm",Larvae,0.1831,1.2009,83.268,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus moluccensis,Trop,Yes,Habitat,"% time in hard coral cue, hard coral vs. rubble, 700 ppm",Larvae,0.1178,1.125,88.887,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus moluccensis,Trop,Yes,Habitat,"% time in hard coral cue, hard coral vs. rubble, 850 ppm",Larvae,0.0474,1.0485,95.371,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus moluccensis,Trop,Yes,Habitat,"% time in soft coral cue, soft coral vs.rubble, 700 ppm",Larvae,0.2053,1.2279,81.44,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus moluccensis,Trop,Yes,Habitat,"% time in soft coral cue, soft coral vs.rubble, 850 ppm",Larvae,0.4263,1.5316,65.292,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus amboinensis,Trop,Yes,Habitat,"% time in hard coral cue, hard vs. soft coral, 700 ppm",Larvae,0.0498,1.0511,95.142,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus amboinensis,Trop,Yes,Habitat,"% time in hard coral cue, hard vs. soft coal, 850 ppm",Larvae,0.1349,1.1444,87.38,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus amboinensis,Trop,Yes,Habitat,"% time in hard coral cue, hard coral vs. rubble, 700 ppm",Larvae,0.0726,1.0753,92.997,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus amboinensis,Trop,Yes,Habitat,"% time in hard coral cue, hard coral vs. rubble, 850 ppm",Larvae,0.2357,1.2658,79.002,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus amboinensis,Trop,Yes,Habitat,"% time in soft coral cue, soft coral vs. rubble, 700 ppm",Larvae,0.2675,1.3067,76.529,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus amboinensis,Trop,Yes,Habitat,"% time in soft coral cue, soft coral vs. rubble, 850 ppm",Larvae,0.0741,1.0769,92.858,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus chrysurus,Trop,Yes,Habitat,"% time in hard coral cue, hard vs. soft coral, 700 ppm",Larvae,0.087,1.0909,91.668,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus chrysurus,Trop,Yes,Habitat,"% time in hard coral cue, hard vs. soft coral, 850 ppm",Larvae,0.1658,1.1803,84.722,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus chrysurus,Trop,Yes,Habitat,"% time in hard coral cue, hard coral vs. rubble, 700 ppm",Larvae,0.107,1.1129,89.853,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus chrysurus,Trop,Yes,Habitat,"% time in hard coral cue, hard coral vs. rubble, 850 ppm",Larvae,0.5914,1.8065,55.355,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus chrysurus,Trop,Yes,Habitat,"% time in soft coral cue, soft coral vs. rubble, 700 ppm",Larvae,0.0527,1.0541,94.866,
a9,Devine et al,2011,2012,Rising CO2 concentrations affect settlement behaviour of larval damselfishes,Coral Reefs,3.878,3.095,Pomacentrus chrysurus,Trop,Yes,Habitat,"% time in soft coral cue, soft coral vs. rubble, 850 ppm",Larvae,0.2809,1.3243,75.51,
a10,Domenici et al,2011,2012,Elevated carbon dioxide affects behavioural lateralization in a coral reef fish,Biol Lett,3.762,3.345,Neopomacentrus azysron,Trop,No,null,Absolute lateralization ,Larvae,0.475,1.608,62.189,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in feeding strikes, pseudo-conditioning, water, Fig 1",Juvenile,2.9448,19.0069,5.261,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, pseudo-conditioning, predator, Fig 1",Juvenile,1.4585,4.2995,23.258,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in feeding strikes, true conditioning, water, Fig 1",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, true conditioning, predator, Fig 1",Juvenile,3.3291,27.9132,3.583,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in line crosses, pseudo-conditioning, water, Fig 1",Juvenile,1.8968,6.6645,15.005,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, pseudo-conditioning, predator, Fig 1",Juvenile,1.386,3.9988,25.007,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in line crosses, true conditioning, water, Fig 1",Juvenile,0.5598,1.7503,57.132,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, true conditioning, predator, Fig 1",Juvenile,3.599,36.5617,2.735,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in area use, pseudo-conditioning, water, Fig 1",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, pseudo-conditioning, predator, Fig 1",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in area use, true conditioning, water, Fig 1",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, true conditioning, predator, Fig 1",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in feeding strikes, naďve tutor, water, Fig 2",Juvenile,0.6131,1.8461,54.167,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, naďve tutor, predator, Fig 2",Juvenile,2.4683,11.8024,8.473,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in feeding strikes, experienced tutor, water, Fig 2",Juvenile,0.4706,1.601,62.463,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, experienced tutor, predator, Fig 2",Juvenile,2.2362,9.3577,10.686,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in line crosses, naďve tutor, water, Fig 2",Juvenile,0.1542,1.1667,85.71,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, naďve tutor, predator, Fig 2",Juvenile,0.6131,1.8461,54.167,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in line crosses, experienced tutor, water, Fig 2",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, experienced tutor, predator, Fig 2",Juvenile,2.9874,19.834,5.042,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in area use, naďve tutor, water, Fig 2",Juvenile,0.6931,1.9999,50.002,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, naďve tutor, predator, Fig 2",Juvenile,2.0346,7.6492,13.073,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in area use, experienced tutor, water, Fig 2",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, experienced tutor, predator, Fig 2",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in feeding strikes, water, Fig 3",Juvenile,0.1054,1.1112,89.996,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, predator, Fig 3",Juvenile,1.2527,3.4998,28.573,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in line crosses , water, Fig 3",Juvenile,0.4594,1.5831,63.166,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, predator, Fig 3",Juvenile,0.7658,2.1507,46.496,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in area use, water, Fig 3",Juvenile,0.2238,1.2508,79.948,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, predator, Fig 3",Juvenile,2.316,10.1351,9.867,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in feeding strikes, water, Fig 4",Juvenile,0.3364,1.3999,71.434,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, predator, Fig 4",Juvenile,1.6752,5.3399,18.727,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in feeding strikes, conspecifics, Fig 4",Juvenile,0.0684,1.0708,93.389,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in line crosses, water, Fig 4",Juvenile,0.9616,2.6159,38.228,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, predator, Fig 4",Juvenile,1.0328,2.8089,35.601,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in line crosses, conspecifics, Fig 4",Juvenile,0.3184,1.3749,72.731,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,No,null,"Change in area use, water, Fig 4",Juvenile,NA,NA,NA,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, predator, Fig 4",Juvenile,1.5295,4.6159,21.664,
a11,Ferrari et al ,2012,2012,Effects of Ocean Acidification on Learning in Coral Reef Fishes,PLOS One,3.73,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,"Change in area use, conspecifics, Fig 4",Juvenile,0.5448,1.7243,57.996,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease feeding, 550 uatm",Juvenile,0.0168,1.0169,98.334,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease feeding, 700 uatm",Juvenile,0.0456,1.0467,95.542,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease feeding, 850 uatm",Juvenile,0.5149,1.6735,59.756,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease line crosses, 550 uatm",Juvenile,0.089,1.0931,91.485,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease line crosses, 700 uatm",Juvenile,0.1993,1.2205,81.93,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease line crosses, 850 uatm",Juvenile,6.3063,548.0135,0.182,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease area use, 550 uatm",Juvenile,0.0064,1.0064,99.362,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease area use, 700 uatm",Juvenile,0.0835,1.0871,91.989,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Prop decrease area use, 850 uatm",Juvenile,1.6257,5.082,19.677,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Min approach distance, 550 uatm",Juvenile,0.1359,1.1456,87.293,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Min approach distance, 700 uatm",Juvenile,0.0224,1.0227,97.785,
a12,Ferrari et al ,2012,2012,Effects of ocean acidification on visual risk assessment in coral reef fishes,Funct Ecol,4.861,5.491,Pomacentrus amboinensis,Trop,Yes,Food,"Min approach distance, 850 uatm",Juvenile,0.2712,1.3115,76.246,
a13,Hurst et al,2012,2012,Resiliency of juvenile walleye pollock to projected levels of ocean acidification,Mar Ecol Prog Ser,2.546,2.276,Theragra chalcogramma,Temp,No,null,"Consumption rate, cold phase, point 1",Juvenile,0.0513,1.0526,94.999,
a13,Hurst et al,2012,2012,Resiliency of juvenile walleye pollock to projected levels of ocean acidification,Mar Ecol Prog Ser,2.546,2.276,Theragra chalcogramma,Temp,No,null,"Consumption rate, cold phase, point 2",Juvenile,0.1054,1.1112,89.996,
a13,Hurst et al,2012,2012,Resiliency of juvenile walleye pollock to projected levels of ocean acidification,Mar Ecol Prog Ser,2.546,2.276,Theragra chalcogramma,Temp,No,null,"Consumption rate, cold phase, point 3",Juvenile,0.1054,1.1112,89.996,
a13,Hurst et al,2012,2012,Resiliency of juvenile walleye pollock to projected levels of ocean acidification,Mar Ecol Prog Ser,2.546,2.276,Theragra chalcogramma,Temp,No,null,"Consumption rate, warm phase, point 1",Juvenile,0.0599,1.0617,94.186,
a13,Hurst et al,2012,2012,Resiliency of juvenile walleye pollock to projected levels of ocean acidification,Mar Ecol Prog Ser,2.546,2.276,Theragra chalcogramma,Temp,No,null,"Consumption rate, warm phase, point 2",Juvenile,0.0482,1.0494,95.294,
a13,Hurst et al,2012,2012,Resiliency of juvenile walleye pollock to projected levels of ocean acidification,Mar Ecol Prog Ser,2.546,2.276,Theragra chalcogramma,Temp,No,null,"Consumption rate, warm phase, point 3",Juvenile,0.0482,1.0494,95.294,
a14,Nilsson et al,2012,2012,Near-future carbon dioxide levels alter fish behaviour by interfering with neurotransmitter function,Nat Clim Chang,14.472,19.181,Amphiprion percula,Trop,Yes,Predator,"% time in cue, pred vs. seawater",Larvae,4.465,86.921,1.15,
a14,Nilsson et al,2012,2012,Near-future carbon dioxide levels alter fish behaviour by interfering with neurotransmitter function,Nat Clim Chang,14.472,19.181,Amphiprion percula,Trop,Yes,Predator,"% time in cue, pred vs. non-pred",Larvae,1.9944,7.3478,13.61,
a14,Nilsson et al,2012,2012,Near-future carbon dioxide levels alter fish behaviour by interfering with neurotransmitter function,Nat Clim Chang,14.472,19.181,Neopomacentrus azysron,Trop,No,null,Absolute lateralization,Larvae,0.2843,1.3288,75.254,
a15,Nowicki et al,2012,2012,Interactive effects of elevated temperature and CO2 on foraging behavior of juvenile coral reef fish,J Exp Mar Biol Ecol,2.263,1.99,Amphiprion melanopus,Trop,No,null,"Line crosses (routine), Mid CO2",Juvenile,0.3685,1.4456,69.177,
a15,Nowicki et al,2012,2012,Interactive effects of elevated temperature and CO2 on foraging behavior of juvenile coral reef fish,J Exp Mar Biol Ecol,2.263,1.99,Amphiprion melanopus,Trop,No,null,"Line crosses (routine), High CO2",Juvenile,0.2822,1.326,75.412,
a15,Nowicki et al,2012,2012,Interactive effects of elevated temperature and CO2 on foraging behavior of juvenile coral reef fish,J Exp Mar Biol Ecol,2.263,1.99,Amphiprion melanopus,Trop,Yes,Food,"Food strikes, Mid CO2",Juvenile,0.0616,1.0635,94.026,
a15,Nowicki et al,2012,2012,Interactive effects of elevated temperature and CO2 on foraging behavior of juvenile coral reef fish,J Exp Mar Biol Ecol,2.263,1.99,Amphiprion melanopus,Trop,Yes,Food,"Food strikes, High CO2",Juvenile,0.1793,1.1964,83.586,
a15,Nowicki et al,2012,2012,Interactive effects of elevated temperature and CO2 on foraging behavior of juvenile coral reef fish,J Exp Mar Biol Ecol,2.263,1.99,Amphiprion melanopus,Trop,Yes,Food,"Line crosses (feeding), Mid CO2",Juvenile,0.0462,1.0473,95.485,
a15,Nowicki et al,2012,2012,Interactive effects of elevated temperature and CO2 on foraging behavior of juvenile coral reef fish,J Exp Mar Biol Ecol,2.263,1.99,Amphiprion melanopus,Trop,Yes,Food,"Line crosses (feeding), High CO2",Juvenile,0.0567,1.0583,94.488,
a16,Sundin et al,2012,2012,Altered Oceanic pH Impairs Mating Propensity in a Pipefish,Ethology,1.947,1.697,Syngnathus typhle,Temp,Yes,Mate,Time swimming,Adult,0.1417,1.1522,86.788,
a17,Allan et al ,2013,2013,Elevated CO2 Affects Predator-Prey Interactions through Altered Performance,PLOS One,3.534,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,Reaction distance,Larvae,0.3331,1.3953,71.67,
a17,Allan et al ,2013,2013,Elevated CO2 Affects Predator-Prey Interactions through Altered Performance,PLOS One,3.534,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,Apparent looming threshold,Larvae,0.0888,1.0929,91.503,
a17,Allan et al ,2013,2013,Elevated CO2 Affects Predator-Prey Interactions through Altered Performance,PLOS One,3.534,2.766,Pomacentrus amboinensis,Trop,Yes,Predator,Escape distance,Larvae,0.579,1.7843,56.046,
a17,Allan et al ,2013,2013,Elevated CO2 Affects Predator-Prey Interactions through Altered Performance,PLOS One,3.534,2.766,Pseudochromis fuscus,Trop,Yes,Prey,Predation rate,Larvae,0.4195,1.5212,65.738,
a17,Allan et al ,2013,2013,Elevated CO2 Affects Predator-Prey Interactions through Altered Performance,PLOS One,3.534,2.766,Pseudochromis fuscus,Trop,Yes,Prey,Predator attack distance,Larvae,0.121,1.1286,88.603,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,No,null,"Mean track length, Mid CO2, routine",Larvae,0.0736,1.0764,92.904,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,No,null,"Mean track length, High CO2, routine",Larvae,0.0515,1.0528,94.98,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,No,null,"Mean speed, Mid CO2, routine",Larvae,0.068,1.0704,93.426,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,No,null,"Mean speed, High CO2, routine",Larvae,0.029,1.0294,97.142,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,No,null,"Max speed, Mid CO2, routine",Larvae,0.1115,1.118,89.449,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,No,null,"Max speed, High CO2, routine",Larvae,0.024,1.0243,97.629,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,Yes,Food,"Mean track length, Mid CO2, olfactory stimulation",Larvae,0.0506,1.0519,95.066,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,Yes,Food,"Mean track length, High CO2, olfactory stimulation",Larvae,0.1684,1.1834,84.502,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,Yes,Food,"Mean speed, Mid CO2, olfactory stimulation",Larvae,0.0649,1.0671,93.716,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,Yes,Food,"Mean speed, High CO2, olfactory stimulation",Larvae,0.1881,1.207,82.853,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,Yes,Food,"Max speed, Mid CO2, olfactory stimulation",Larvae,0.1421,1.1527,86.753,
a18,Bignami et al,2012,2013,"Response to ocean acidification in larvae of a large tropical marine fish, Rachycentron canadum",Glob Change Biol,6.91,8.997,Rachycentron canadum,Subtrop,Yes,Food,"Max speed, High CO2, olfactory stimulation",Larvae,0.1537,1.1661,85.753,
a19,Forsgen et al,2013,2013,Elevated CO 2 affects embryonic development and larval phototaxis in a temperate marine fish,Ecol Evol,1.658,2.34,Gobiusculus flavescens,Temp,Yes,Light,Phototaxis,Larvae,0.5575,1.7463,57.264,
a19,Forsgen et al,2013,2013,Elevated CO 2 affects embryonic development and larval phototaxis in a temperate marine fish,Ecol Evol,1.658,2.34,Gobiusculus flavescens,Temp,Yes,Light,Swim time,Larvae,0.4849,1.624,61.576,
a20,Jutfelt & Hedgarde,2013,2013,"Atlantic cod actively avoid CO2 and predator odour, even after long-term CO2 exposure",Front Zool,2.304,3.627,Gadus morhua,Temp,Yes,Physical Seawater,% time in control water (vs. CO2 water),Juvenile,0.0479,1.0491,95.323,
a20,Jutfelt & Hedgarde,2013,2013,"Atlantic cod actively avoid CO2 and predator odour, even after long-term CO2 exposure",Front Zool,2.304,3.627,Gadus morhua,Temp,Yes,Predator,% time in control water (vs. predator cue),Juvenile,0.0129,1.013,98.718,
a21,Jutfelt et al,2013,2013,Behavioural Disturbances in a Temperate Fish Exposed to Sustained High-CO2 Levels,PLOS One,3.534,2.766,Gasterosteus aculeatus,Subtrop,No,null,Absolute lateralization 20 days,Adult,0.6616,1.9379,51.603,
a21,Jutfelt et al,2013,2013,Behavioural Disturbances in a Temperate Fish Exposed to Sustained High-CO2 Levels,PLOS One,3.534,2.766,Gasterosteus aculeatus,Subtrop,No,null,Absolute lateralization 40 days,Adult,1.2456,3.475,28.777,
a21,Jutfelt et al,2013,2013,Behavioural Disturbances in a Temperate Fish Exposed to Sustained High-CO2 Levels,PLOS One,3.534,2.766,Gasterosteus aculeatus,Subtrop,Yes,Novel object,Time spent investigating,Adult,1.5927,4.917,20.338,
a21,Jutfelt et al,2013,2013,Behavioural Disturbances in a Temperate Fish Exposed to Sustained High-CO2 Levels,PLOS One,3.534,2.766,Gasterosteus aculeatus,Subtrop,Yes,Shelter,Escape time 20 days,Adult,0.2794,1.3223,75.624,
a21,Jutfelt et al,2013,2013,Behavioural Disturbances in a Temperate Fish Exposed to Sustained High-CO2 Levels,PLOS One,3.534,2.766,Gasterosteus aculeatus,Subtrop,Yes,Shelter,Escape time 40 days,Adult,1.78,5.9299,16.864,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change bite rate, conspecific skin, Fig1",Larvae,2.1173,8.3087,12.036,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change bite rate, heterospecific skin, Fig1",Larvae,1.1788,3.2505,30.765,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,No,null,"Mean change bite rate, saltwater control, Fig1",Larvae,0.3189,1.3756,72.695,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change activity, conspecific skin, Fig1",Larvae,2.6578,14.2649,7.01,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change activity, heterospecific skin, Fig1",Larvae,1.05,2.8577,34.994,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,No,null,"Mean change activity, saltwater control, Fig1",Larvae,0.1172,1.1243,88.941,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change in shelter use, conspecific skin, Fig1",Larvae,2.5256,12.4984,8.001,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change in shelter use, heterospecific skin, Fig1",Larvae,0.7888,2.2008,45.439,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,No,null,"Mean change in shelter use, saltwater control, Fig1",Larvae,9.7075,16440.4493,0.006,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change bite rate, predator, Fig2",Larvae,0.1586,1.1719,85.334,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Kin,"Mean change bite rate, goby, Fig2",Larvae,2.3972,10.9924,9.097,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,No,null,"Mean change bite rate, empty bag, Fig2",Larvae,NA,NA,NA,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change activity, predator, Fig2",Larvae,0.1593,1.1727,85.274,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Kin,"Mean change activity, goby, Fig2",Larvae,1.0414,2.8332,35.296,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,No,null,"Mean change activity, empty bag, Fig2",Larvae,0.3023,1.353,73.912,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change shelter use, predator, Fig2",Larvae,0.9406,2.5615,39.039,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Kin,"Mean change shelter use, goby, Fig2",Larvae,NA,NA,NA,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,No,null,"Mean change shelter use, empty bag, Fig2",Larvae,NA,NA,NA,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change bite rate, skin, Fig3",Larvae,2.1482,8.5694,11.669,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change bite rate, predator, Fig3",Larvae,0.1474,1.1588,86.295,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change bite rate, combo, Fig3",Larvae,0.3365,1.4,71.427,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change activity, skin, Fig3",Larvae,2.5386,12.6619,7.898,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change activity, predator, Fig3",Larvae,0.1671,1.1819,84.611,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change activity, combo, Fig3",Larvae,0.4266,1.532,65.272,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change shelter use, skin, Fig3",Larvae,2.708,14.9992,6.667,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change shelter use, predator, Fig3",Larvae,0.9593,2.6099,38.316,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Mean change shelter use, combo, Fig3",Larvae,0.9163,2.5,40,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Number of bobbing events, skin extract",Larvae,8.4316,4589.838,0.022,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Number of bobbing events, predator",Larvae,2.5006,12.1898,8.204,
a22,Lönnstedt et al,2013,2013,Ocean acidification and responses to predators: can sensory redundancy reduce the apparent impacts of elevated CO2 on fish?,Ecol Evol,1.658,2.34,Pomacentrus amboinensis,Trop,Yes,Predator,"Number of bobbing events, combo",Larvae,1.9379,6.9442,14.401,
a23,McCormick et al,2013,2013,Ocean acidification reverses competition for space as habitats degrade,Sci Rep,5.078,4.122,Pomacentrus moluccensis,Trop,Yes,Shelter,Distance ventured from shelter,Larvae,0.1386,1.1487,87.058,
a23,McCormick et al,2013,2013,Ocean acidification reverses competition for space as habitats degrade,Sci Rep,5.078,4.122,Pomacentrus amboinensis,Trop,Yes,Shelter,Distance ventured from shelter,Larvae,1.3173,3.7333,26.786,
a23,McCormick et al,2013,2013,Ocean acidification reverses competition for space as habitats degrade,Sci Rep,5.078,4.122,Pomacentrus moluccensis,Trop,Yes,Shelter,Height rank,Larvae,0.2326,1.2619,79.247,
a23,McCormick et al,2013,2013,Ocean acidification reverses competition for space as habitats degrade,Sci Rep,5.078,4.122,Pomacentrus amboinensis,Trop,Yes,Shelter,Height rank,Larvae,0.4874,1.6281,61.422,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Predator,"% time in cue, 570 uatm, Day 4",Juvenile,0.4895,1.6315,61.293,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Predator,"% time in cue, 700 uatm, Day 4",Juvenile,2.0183,7.5255,13.288,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Predator,"% time in cue, 960 uatm, Day 4",Juvenile,2.6831,14.6304,6.835,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Predator,"% time in cue, 570 uatm, Day 28",Juvenile,0.1644,1.1787,84.84,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Predator,"% time in cue, 700 uatm, Day 28",Juvenile,1.6376,5.1428,19.445,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Predator,"% time in cue, 960 uatm, Day 28",Juvenile,2.2919,9.8937,10.107,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"% time hiding, 570 uatm",Juvenile,0.0628,1.0648,93.913,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"% time hiding, 700 uatm",Juvenile,0.7019,2.0176,49.564,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"% time hiding, 960 uatm",Juvenile,2.1799,8.8454,11.305,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Mean line crosses, 570 uatm",Juvenile,0.6931,1.9999,50.002,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Mean line crosses, 700 uatm",Juvenile,2.1972,8.9998,11.111,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Mean line crosses, 960 uatm",Juvenile,4.1666,64.4958,1.55,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Distance from shelter, 570 uatm",Juvenile,0.7841,2.1904,45.653,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Distance from shelter, 700 uatm",Juvenile,1.5606,4.7617,21.001,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Distance from shelter, 960 uatm",Juvenile,1.7512,5.7615,17.357,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Emergence time from hiding, 570 uatm",Juvenile,0.069,1.0714,93.333,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Emergence time from hiding, 700 uatm",Juvenile,0.3365,1.4,71.427,
a24,Munday et al,2012,2013,Elevated CO2 affects the behavior of an ecologically and economically important coral reef fish,Mar Biol,2.468,2.215,Plectropomus leopardus,Trop,Yes,Shelter,"Emergence time from hiding, 960 uatm",Juvenile,1.674,5.3335,18.75,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Response distance, ctrl-high",Juvenile,0.3166,1.3725,72.862,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Response distance, high-high",Juvenile,0.1053,1.111,90.005,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Mean speed, ctrl-high",Juvenile,0.3067,1.3589,73.587,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Mean speed, high-high",Juvenile,0.0908,1.095,91.32,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Maximum speed, ctrl-high",Juvenile,0.3041,1.3554,73.779,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Maximum speed, high-high",Juvenile,0.0661,1.0683,93.604,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Response duration, ctrl-high",Juvenile,0.4407,1.5538,64.359,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Response duration, high-high",Juvenile,0.2195,1.2455,80.292,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Response latency, ctrl-high",Juvenile,0.0253,1.0256,97.502,
a25,Allan et al,2014,2014,Parental effects improve escape performance of juvenile reef fish in a high-CO2 world,Proc R Soc B,5.051,4.847,Amphiprion melanopus,Trop,Yes,Mimicked threat,"Response latency, high-high",Juvenile,0.0785,1.0817,92.45,
a26,Bignami et al,2014,2014,"Effects of ocean acidification on the larvae of a high-value pelagic fisheries species, mahi-mahi Coryphaena hippurus",Mar Ecol Prog Ser,2.619,2.276,Coryphaena hippurus,Subtrop,No,null,"Max velocity, 770 uatm",Larvae,0.1532,1.1656,85.796,
a26,Bignami et al,2014,2014,"Effects of ocean acidification on the larvae of a high-value pelagic fisheries species, mahi-mahi Coryphaena hippurus",Mar Ecol Prog Ser,2.619,2.276,Coryphaena hippurus,Subtrop,No,null,"Max velocity, 1460 uatm",Larvae,0.257,1.293,77.337,
a26,Bignami et al,2014,2014,"Effects of ocean acidification on the larvae of a high-value pelagic fisheries species, mahi-mahi Coryphaena hippurus",Mar Ecol Prog Ser,2.619,2.276,Coryphaena hippurus,Subtrop,No,null,"Mean velocity, 770 uatm",Larvae,0.1553,1.168,85.616,
a26,Bignami et al,2014,2014,"Effects of ocean acidification on the larvae of a high-value pelagic fisheries species, mahi-mahi Coryphaena hippurus",Mar Ecol Prog Ser,2.619,2.276,Coryphaena hippurus,Subtrop,No,null,"Mean velocity, 1460 uatm",Larvae,0.2352,1.2652,79.041,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,No,null,"Prop change line crosses, Day 1, sham",Juvenile,NA,NA,NA,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,No,null,"Prop change feeding strikes, Day 1, sham",Juvenile,NA,NA,NA,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,Yes,Predator,"Prop change line crosses, Day 1, predator",Juvenile,1.3915,4.0209,24.87,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,Yes,Predator,"Prop change feeding strikes, Day 1, predator",Juvenile,1.731,5.6463,17.711,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,No,null,"Prop change line crosses, Day 5, sham",Juvenile,NA,NA,NA,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,No,null,"Prop change feeding strikes, Day 5, sham",Juvenile,0.7167,2.0477,48.836,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,Yes,Predator,"Prop change line crosses, Day 5, predator",Juvenile,1.9592,7.0936,14.097,
a27,Chivers et al,2013,2014,Impaired learning of predators and lower prey survival under elevated CO2: a consequence of neurotransmitter interference,Glob Change Biol,8.224,8.997,Pomacentrus amboinensis,Trop,Yes,Predator,"Prop change feeding strikes, Day 5, predator",Juvenile,3.3064,27.2867,3.665,
a28,Domenici et al,2014,2014,Shifting from Right to Left: The Combined Effect of Elevated CO2 and Temperature on Behavioural Lateralization in a Coral Reef Fish,PLOS One,3.234,2.766,Pomacentrus wardi,Trop,No,null,Absolute lateralization,Larvae,0.1266,1.135,88.109,
a29,Green & Jutfelt,2014,2014,Elevated carbon dioxide alters the plasma composition and behaviour of a shark,Biol Lett,3.248,3.345,Scyliorhinus canicula,Subtrop,No,null,Absolute lateralization,Adult,0.7331,2.0815,48.042,
a29,Green & Jutfelt,2014,2014,Elevated carbon dioxide alters the plasma composition and behaviour of a shark,Biol Lett,3.248,3.345,Scyliorhinus canicula,Subtrop,No,null,No. swimming events,Adult,0.7365,2.0886,47.879,
a30,Hamilton et al,2013,2014,CO2-induced ocean acidification increases anxiety in Rockfish via alteration of GABAA receptor functioning,Proc R Soc B,5.292,4.847,Sebastes diploproa,Deep,Yes,Shelter,% time in dark zone,Juvenile,0.4949,1.6403,60.963,
a30,Hamilton et al,2013,2014,CO2-induced ocean acidification increases anxiety in Rockfish via alteration of GABAA receptor functioning,Proc R Soc B,5.292,4.847,Sebastes diploproa,Deep,Yes,Shelter,Time near object,Juvenile,0.5257,1.6916,59.114,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Predator,% time in predator cue (Fig 1a),Juvenile,13.7928,977545.3856,0,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Predator,% time in predator cue (Fig 1a),Juvenile,13.7166,905823.7231,0,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Predator,% time in predator cue (Fig 1a),Juvenile,13.7602,946191.2551,0,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Predator,% time in predator cue (Fig 1a),Juvenile,13.802,986580.3,0,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Physical Seawater,% time in control cue (Fig 1b),Juvenile,0.66,1.9348,51.685,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Physical Seawater,% time in control cue (Fig 1b),Juvenile,0.6201,1.8591,53.789,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Physical Seawater,% time in control cue (Fig 1b),Juvenile,0.6185,1.8561,53.875,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Physical Seawater,% time in control cue (Fig 1b),Juvenile,0.5901,1.8042,55.427,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Habitat,% time in benthic control (Fig 1c),Juvenile,0.6291,1.8759,53.307,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Habitat,% time in benthic control (Fig 1c),Juvenile,0.6131,1.8461,54.167,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Habitat,% time in benthic control (Fig 1c),Juvenile,0.5725,1.7727,56.411,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Habitat,% time in benthic control (Fig 1c),Juvenile,0.604,1.8294,54.662,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Shelter,Mean % time in shelter,Juvenile,2.3513,10.4992,9.525,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Shelter,Mean % time in shelter,Juvenile,2.6311,13.889,7.2,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Shelter,Mean % time in shelter,Juvenile,13.6459,843993.4391,0,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Shelter,Mean % time in shelter,Juvenile,13.5941,801387.5967,0,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Shelter,Mean line crosses,Juvenile,1.1686,3.2175,31.08,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Shelter,Mean line crosses,Juvenile,1.5405,4.6669,21.427,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Shelter,Mean line crosses,Juvenile,2.2482,9.4707,10.559,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Shelter,Mean line crosses,Juvenile,1.6362,5.1356,19.472,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Shelter,Max distance from shelter,Juvenile,0.8027,2.2316,44.812,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Shelter,Max distance from shelter,Juvenile,0.7349,2.0853,47.955,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Shelter,Max distance from shelter,Juvenile,0.9234,2.5178,39.717,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Shelter,Max distance from shelter,Juvenile,1.1497,3.1572,31.673,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Dascyllus aruanus,Trop,Yes,Shelter,Time to emerge from shelter,Juvenile,1.4935,4.4527,22.459,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Pomacentrus moluccensis,Trop,Yes,Shelter,Time to emerge from shelter,Juvenile,1.6096,5.0008,19.997,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Apogon cyanosoma,Trop,Yes,Shelter,Time to emerge from shelter,Juvenile,1.6645,5.283,18.929,
a31,Munday et al,2014,2014,Behavioural impairment in reef fishes caused by ocean acidification at CO2 seeps,Nat Clim Change,14.547,19.181,Cheilodipterus quinquelineatus,Trop,Yes,Shelter,Time to emerge from shelter,Juvenile,2.14,8.4994,11.765,
a32,Pimentel et al,2014,2014,Impact of ocean acidification in the metabolism and swimming behavior of the dolphinfish (Coryphaena hippurus) early larvae,Mar Biol,2.391,2.215,Coryphaena hippurus,Subtrop,No,null,Swimming duration,Larvae,0.6822,1.9782,50.55,
a32,Pimentel et al,2014,2014,Impact of ocean acidification in the metabolism and swimming behavior of the dolphinfish (Coryphaena hippurus) early larvae,Mar Biol,2.391,2.215,Coryphaena hippurus,Subtrop,No,null,% active,Larvae,0.674,1.9621,50.967,
a32,Pimentel et al,2014,2014,Impact of ocean acidification in the metabolism and swimming behavior of the dolphinfish (Coryphaena hippurus) early larvae,Mar Biol,2.391,2.215,Coryphaena hippurus,Subtrop,No,null,Orientation frequency,Larvae,0.9842,2.6757,37.374,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in cue, Mid CO2, ctrl parents",Juvenile,1.6188,5.047,19.814,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in cue, High CO2, ctrl parents",Juvenile,1.9636,7.1249,14.035,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in cue, Mid CO2, mid parents",Juvenile,1.5798,4.854,20.602,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in cue, High CO2, mid parents",Juvenile,1.9033,6.708,14.908,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in cue, Mid CO2, high parents",Juvenile,1.5269,4.6039,21.721,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in cue, High CO2, high parents",Juvenile,1.9033,6.708,14.908,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Mid CO2, ctrl parents",Juvenile,0.4891,1.6308,61.318,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, High CO2, ctrl parents",Juvenile,0.6526,1.9205,52.069,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Mid CO2, mid parents",Juvenile,0.4759,1.6095,62.133,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, High CO2, mid parents",Juvenile,0.5656,1.7605,56.802,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Mid CO2, high parents",Juvenile,0.3508,1.4202,70.412,
a33,Welch et al,2014,2014,Effects of elevated CO2 on fish behaviour undiminished by transgenerational acclimation,Nat Clim Change,14.547,19.181,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, High CO2, high parents",Juvenile,0.4249,1.5294,65.384,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, bare substrate",Adult,0.0298,1.0302,97.064,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Gelidiella",Adult,0.5306,1.7,58.825,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Ceramium",Adult,0,1,100,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Centroceras",Adult,0.7473,2.1113,47.364,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Laurencia",Adult,NA,NA,NA,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Hypnea",Adult,NA,NA,NA,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Coelothrix irregularis",Adult,NA,NA,NA,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Polysiphonia",Adult,0.1503,1.1622,86.045,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, calcifying red",Adult,0.9163,2.5,40,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, cyanobacteria",Adult,0.3365,1.4,71.427,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, cyanobacteria eipphytic",Adult,1.0481,2.8522,35.06,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate,Feldmannia mitchelliae",Adult,1.6094,4.9998,20.001,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Sphacelaria",Adult,0,1,100,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, misc brown algae",Adult,0.8106,2.2493,44.459,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Cladophora",Adult,0.7348,2.0851,47.96,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Ulva",Adult,0.592,1.8076,55.322,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, Derbesia fastigiata",Adult,1.4917,4.4446,22.499,
a34,Bender et al,2015,2015,Effects of “Reduced” and “Business-As-Usual” CO2 Emission Scenarios on the Algal Territories of the Damselfish Pomacentrus wardi (Pomacentridae),PloS One,3.057,2.766,Pomacentrus wardi,Trop,Yes,Food,"Feeding rate, misc green algae",Adult,0.6936,2.0009,49.977,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"% time in cue, Mid CO2",Adult,0.0123,1.0124,98.778,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"% time in cue, High CO2",Adult,1.5612,4.7645,20.988,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean lines crossed, Mid CO2, preferred side",Adult,0.2995,1.3492,74.119,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean lines crossed, High CO2, preferred side",Adult,0.0312,1.0317,96.928,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean lines crossed, Mid CO2, non-preferred side",Adult,0.1158,1.1228,89.065,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean lines crossed, High CO2, non-preferred side",Adult,0.4212,1.5238,65.626,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,No,null,"Mean lines crossed, Mid CO2, seawater",Adult,0.1711,1.1866,84.274,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,No,null,"Mean lines crossed, High CO2, seawater",Adult,0,1,100,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bumps, Mid CO2, preferred side",Adult,0.9445,2.5715,38.887,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bumps, High CO2, preferred side",Adult,2.8904,18.0005,5.555,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bumps, Mid CO2, non-preferred side",Adult,1.0809,2.9473,33.929,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bumps, Mid CO2, non-preferred side",Adult,1.583,4.8695,20.536,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bites, Mid CO2, preferred side",Adult,3.0799,21.7562,4.596,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bites, High CO2, preferred side",Adult,4.4662,87.0254,1.149,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bites, Mid CO2, non-preferred side",Adult,2.5526,12.8404,7.788,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"Mean bites, High CO2, non-preferred side",Adult,2.3973,10.9935,9.096,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"% time in cue, Mid CO2, preferred side",Adult,0.0345,1.0351,96.609,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"% time in cue, High CO2, preferred side",Adult,0.9508,2.5878,38.643,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"% time in cue, Mid CO2, non-preferred side",Adult,0.215,1.2399,80.654,
a35,Dixson et al,2014,2015,Odor tracking in sharks is reduced under future ocean acidification conditions,Glob Change Biol,8.044,8.997,Mustelus canis,Subtrop,Yes,Food,"% time in cue, High CO2, non-preferred side",Adult,2.3815,10.8211,9.241,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,Yes,Food,Feed intake,Adult,1.3944,4.0326,24.798,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,No,null,% resting,Adult,0.2689,1.3085,76.422,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,No,null,% inactive,Adult,0.0834,1.087,91.998,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,No,null,% swinging,Adult,0.5333,1.7045,58.667,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,No,null,% activity,Adult,0.869,2.3845,41.937,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,No,null,% feeding,Adult,1.4404,4.2224,23.683,
a36,Faliero et al,2015,2015,Seahorses under a changing ocean: the impact of warming and acidification on the behaviour and physiology of a poor-swimming bony-armoured fish ,Conserv Physiol,-,3.46,Hippocampus guttulatus ,Temp,No,null,% swimming,Adult,0.0861,1.0899,91.75,
a37,Ferrari et al ,2014,2015,Interactive effects of ocean acidification and rising sea temperatures alter predation rate and predator in reef fish communities selectivity,Glob Change Biol,8.044,8.997,Pseudochromis fuscus,Trop,Yes,Prey,Predation rate,Juvenile,0,1,100,
a37,Ferrari et al ,2014,2015,Interactive effects of ocean acidification and rising sea temperatures alter predation rate and predator in reef fish communities selectivity,Glob Change Biol,8.044,8.997,Pseudochromis fuscus,Trop,Yes,Prey,Selectivity for prey 1,Juvenile,0.9067,2.4761,40.385,
a37,Ferrari et al ,2014,2015,Interactive effects of ocean acidification and rising sea temperatures alter predation rate and predator in reef fish communities selectivity,Glob Change Biol,8.044,8.997,Pseudochromis fuscus,Trop,Yes,Prey,Selectivity for prey 2,Juvenile,0.8243,2.2803,43.854,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Time outside shelter, Mid CO2",Adult,0.2961,1.3446,74.371,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Time outside shelter, High CO2",Adult,0.0854,1.0892,91.814,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Latency to first bite, Mid CO2",Adult,0.0696,1.0721,93.277,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Latency to first bite, High CO2",Adult,0.494,1.6389,61.018,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Activity shelter food, Mid CO2",Adult,0.0605,1.0624,94.129,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Activity shelter food, High Co2",Adult,0.2072,1.2302,81.286,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Total activity (line crosses), Mid CO2",Adult,0.2917,1.3387,74.699,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Total activity (line crosses), High CO2",Adult,0.1297,1.1385,87.836,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Time to shelter, Mid CO2",Adult,0.0082,1.0082,99.183,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Time to shelter, High CO2",Adult,0.0169,1.017,98.324,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Activity, Mid CO2",Adult,0.0293,1.0297,97.113,
a38,Heinrich et al,2015,2016,Foraging behaviour of the epaulette shark Hemiscyllium ocellatum is not affected by elevated CO2,ICES J Mar Sci,2.626,2.906,Hemiscyllium ocellatum,Trop,Yes,Habitat,"Activity, High CO2",Adult,0.1711,1.1866,84.274,
a39,Jutfelt & Hedgarde,2015,2015,Juvenile Atlantic cod behavior appears robust to near-future CO2 levels,Front Zool,3.042,3.627,Gadus morhua,Temp,No,null,Lines crossed per minute,Juvenile,0.2225,1.2492,80.052,
a39,Jutfelt & Hedgarde,2015,2015,Juvenile Atlantic cod behavior appears robust to near-future CO2 levels,Front Zool,3.042,3.627,Gadus morhua,Temp,Yes,Shelter,Seconds before emergence,Juvenile,0.1231,1.131,88.418,
a39,Jutfelt & Hedgarde,2015,2015,Juvenile Atlantic cod behavior appears robust to near-future CO2 levels,Front Zool,3.042,3.627,Gadus morhua,Temp,No,null,Absolute lateralization,Juvenile,0.2064,1.2292,81.351,
a40,Lai et al,2015,2015,Altered neurotransmitter function in CO2 exposed stickleback (Gasterosteus aculeatus): a temperate model species for ocean acidification research ,Conserv Physiol,-,3.46,Gasterosteus aculeatus,Subtrop,No,null,"Absolute lateralization, 40 days ",Adult,0.8513,2.3427,42.686,
a40,Lai et al,2015,2015,Altered neurotransmitter function in CO2 exposed stickleback (Gasterosteus aculeatus): a temperate model species for ocean acidification research ,Conserv Physiol,-,"3,46",Gasterosteus aculeatus,Subtrop,No,null,"Absolute lateralization, 50 days ",Adult,0.7833,2.1887,45.69,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Move duration, Mid CO2",Larvae,0,1,100,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Move duration, High CO2",Larvae,0,1,100,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Move length, Mid CO2",Larvae,0.1773,1.194,83.753,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Move length, High CO2",Larvae,0.0381,1.0388,96.262,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Move speed, Mid CO2",Larvae,0.0874,1.0913,91.631,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Move speed, High CO2",Larvae,0.0061,1.0061,99.392,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Stop duration, Mid CO2",Larvae,0.2919,1.339,74.684,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"Stop duration, High CO2",Larvae,0,1,100,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO3,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"S-posture (foarging behavior), Mid CO2",Larvae,0.1319,1.141,87.643,
a41,Maneja et al,2015,2015,The swimming kinematics and foraging behavior of larval Atlantic herring (Clupea harengus L.) are unaffected by elevated pCO2,J Exp Mar Biol Ecol,1.796,1.99,Clupea harengus,Temp,No,null,"S-posture (foarging behavior), High CO2",Larvae,0.2334,1.2629,79.184,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"Time to freeze, Day 10",Adult,0.1873,1.206,82.919,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"Freezing duration, Day 10",Adult,0.7176,2.0495,48.792,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"Time to freeze, Day 20",Adult,1.0149,2.7591,36.244,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"Freezing duration, Day 20",Adult,0.641,1.8984,52.677,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,Absolute lateralization,Adult,1.5438,4.6823,21.357,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time HB, pre attack, day 10",Adult,0.468,1.5968,62.625,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time HB post attack, day 10",Adult,0.3054,1.3572,73.683,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time HT, pre attack, day 10",Adult,0.0403,1.0411,96.05,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time HT post attack, day 10",Adult,0.2678,1.3071,76.506,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time OB, pre attack, day 10",Adult,0.4855,1.625,61.539,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time OB post attack, day 10",Adult,0.821,2.2728,43.999,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time OT, pre attack, day 10",Adult,0.3502,1.4194,70.455,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time OT post attack, day 10",Adult,0.1798,1.197,83.544,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time HB, pre attack, day 20",Adult,1.3083,3.6999,27.028,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time HB post attack, day 20",Adult,0.166,1.1806,84.705,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time HT, pre attack, day 20",Adult,0.1974,1.2182,82.086,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time HT post attack, day 20",Adult,0.1904,1.2097,82.663,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time OB, pre attack, day 20",Adult,0.6343,1.8857,53.031,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time OB post attack, day 20",Adult,0.9671,2.6303,38.018,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,No,null,"% time OT, pre attack, day 20",Adult,0.3034,1.3545,73.83,
a42,Naslund et al,2015,2015,Behavioural responses to simulated bird attacks in marine three-spined sticklebacks after exposure to high CO2 levels,Mar Freshw Res,1.583,1.674,Gasterosteus aculeatus,Subtrop,Yes,Mimicked predator,"% time OT post attack, day 20",Adult,0.0278,1.0282,97.258,
a43,Pistevos et al,2015,2015,Ocean acidification and global warming impair shark hunting behaviour and growth,Sci Rep,5.228,4.122,Heterodontus portusjacksoni,Subtrop,Yes,Prey,Food consumption rate,Adult,0.1387,1.1488,87.049,
a43,Pistevos et al,2015,2015,Ocean acidification and global warming impair shark hunting behaviour and growth,Sci Rep,5.228,4.122,Heterodontus portusjacksoni,Subtrop,Yes,Prey,Search time to locate food,Adult,1.5964,4.9352,20.262,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"% time close to speaker, 13-15 days",Larvae,0.0121,1.0122,98.797,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"% time close to speaker, 16-18days",Larvae,0.612,1.8441,54.227,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"% time close to speaker, 19-21 days",Larvae,0.0684,1.0708,93.389,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"% time close to speaker, 22-24 days",Larvae,0.0397,1.0405,96.108,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"% time close to speaker, 25-28 days",Larvae,0.1116,1.1181,89.44,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"Swimming velocity, 13-15 days",Larvae,0.2504,1.2845,77.849,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"Swimming velocity, 16-18days",Larvae,0.2498,1.2838,77.896,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"Swimming velocity, 19-21 days",Larvae,0.0945,1.0991,90.983,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"Swimming velocity, 22-24 days",Larvae,0.1825,1.2002,83.318,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Auditory,"Swimming velocity, 25-28 days",Larvae,0.0402,1.041,96.06,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Shelter,% time in shelter,Larvae,0.2586,1.2951,77.213,
a44,Rossi et al,2015,2015,Ocean acidification boosts larval fish development but reduces the window of opportunity for successful settlement,Proc R Soc B,4.823,4.847,Lates calcarifer,Trop,Yes,Shelter,Time to emergence,Larvae,1.2548,3.5071,28.513,
a45,Duteil et al,2016,2016,European sea bass show behavioural resilience to near-future ocean acidification,R Soc Open Sci,2.243,2.504,Dicentrarchus labrax,Subtrop,Yes,Shelter,Boldness,Adult,0.1481,1.1596,86.234,
a46,Heuer et al,2016,2016,Altered brain ion gradients following compensation for elevated CO2 are linked to behavioural alterations in a coral reef fish,Sci Rep,4.259,4.122,Acanthochromis polyacanthus,Trop,Yes,Predator,% time in CAC,Adult,1.2462,3.4771,28.76,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,Yes,Kin,"Swimming speed, 7 days",Larvae,0.288,1.3338,74.976,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,Yes,Kin,"Swimming speed, 21 days",Larvae,0.0263,1.0266,97.404,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,Yes,Kin,"Nearest neighbour distance, 7 days",Larvae,0.3175,1.3737,72.797,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,Yes,Kin,"Nearest neighbour distance, 21 days",Larvae,0.0823,1.0858,92.1,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,Yes,Kin,"Clark-Evans Index, 7 days",Larvae,0.34,1.4049,71.177,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,Yes,Kin,"Clark-Evans Index, 21 days",Larvae,0.0526,1.054,94.876,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,No,null,"Absolute lateralization, 7 days, Fig 4",Larvae,0.6034,1.8283,54.695,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,No,null,"Absolute lateralization, 21 days, Fig 4",Larvae,0.3747,1.4546,68.75,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,No,null,"Absolute lateralization, Run 1, sham, Fig 5",Larvae,0.2573,1.2934,77.314,
a47,Lopes et al,2016,2016,Behavioural lateralization and shoaling cohesion of fish larvae altered under ocean acidification,Mar Biol,2.136,2.215,Atherina presbyter,Subtrop,No,null,"Absolute lateralization, Run 2, sham, Fig 5",Larvae,0.4968,1.6435,60.847,
a48,Milazzo et al,2016,2016,Ocean acidification affects fish spawning but not paternity at CO2 seeps,Proc R Soc B,4.94,4.847,Symphodus ocellatus,Subtrop,Yes,Mate,Time spent courting,Adult,0.2893,1.3355,74.879,
a48,Milazzo et al,2016,2016,Ocean acidification affects fish spawning but not paternity at CO2 seeps,Proc R Soc B,4.94,4.847,Symphodus ocellatus,Subtrop,Yes,Mate,Number of chasing events per min,Adult,0.2742,1.3155,76.018,
a49,Munday et al,2016,2016,Effects of elevated CO2 on predator avoidance behaviour by reef fishes is not altered by experimental test water,PeerJ,2.177,2.118,Amphiprion percula,Trop,Yes,Predator,% time in predator cue,Larvae,2.1916,8.9495,11.174,
a49,Munday et al,2016,2016,Effects of elevated CO2 on predator avoidance behaviour by reef fishes is not altered by experimental test water,PeerJ,2.177,2.118,Pomacentrus amboinensis,Trop,Yes,Predator,Escape latency,Larvae,0.5232,1.6874,59.262,
a49,Munday et al,2016,2016,Effects of elevated CO2 on predator avoidance behaviour by reef fishes is not altered by experimental test water,PeerJ,2.177,2.118,Pomacentrus amboinensis,Trop,Yes,Predator,Escape speed,Larvae,0.1349,1.1444,87.38,
a49,Munday et al,2016,2016,Effects of elevated CO2 on predator avoidance behaviour by reef fishes is not altered by experimental test water,PeerJ,2.177,2.118,Pomacentrus amboinensis,Trop,Yes,Predator,Escape distance,Larvae,0.1054,1.1112,89.996,
a49,Munday et al,2016,2016,Effects of elevated CO2 on predator avoidance behaviour by reef fishes is not altered by experimental test water,PeerJ,2.177,2.118,Pomacentrus amboinensis,Trop,Yes,Predator,Maximum speed,Larvae,0.1397,1.1499,86.962,
a50,Munday et al,2015,2016,"Effects of elevated CO2 on early life history development of the yellowtail kingfish, Seriola lalandi, a large pelagic fish",ICES J Mar Sci,2.626,2.906,Seriola lalandi,Subtrop,No,null,"Number of line crosses, 880 uatm",Larvae,0.2231,1.2499,80.003,
a50,Munday et al,2015,2016,"Effects of elevated CO2 on early life history development of the yellowtail kingfish, Seriola lalandi, a large pelagic fish",ICES J Mar Sci,2.626,2.906,Seriola lalandi,Subtrop,No,null,"Number of line crosses, 1700 uatm",Larvae,0.1484,1.16,86.209,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Prop time spent w/ shoal, 750 uatm, familiar",Not provided,0.2974,1.3464,74.275,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Prop time spent w/ shoal, 1000 uatm, familiar",Not provided,0.2104,1.2342,81.026,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Prop time spent w/ shoal, 750 uatm, unfamiliar",Not provided,0.3538,1.4245,70.202,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Prop time spent w/ shoal, 1000 uatm, unfamiliar",Not provided,0.2743,1.3156,76.01,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Activity (shoal visits), 700 uatm",Not provided,0.0192,1.0194,98.098,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Activity (shoal visits), 1000 uatm",Not provided,0.0808,1.0842,92.238,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Activity (turns per min), alone, 750 uatm",Not provided,0.8034,2.2331,44.78,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Activity (turns per min), alone, 1000 uatm",Not provided,0.753,2.1234,47.095,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Activity (turns per min), group, 750 uatm",Not provided,0.0547,1.0562,94.677,
a51,Nadler et al,2016,2016,Effect of elevated carbon dioxide on shoal familiarity and metabolism in a coral reef fish,Conserv Physiol,2.323,3.46,Chromis viridis,Subtrop,Yes,Kin,"Activity (turns per min), group, 1000 uatm",Not provided,0.233,1.2624,79.215,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Gobius bucchichi,Subtrop,Yes,Mimicked threat,"Escape speed, bare ",Not provided,0.0678,1.0702,93.445,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Gobius bucchichi,Subtrop,Yes,Mimicked threat,"Escape speed, turf algae",Not provided,0.2031,1.2252,81.62,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Gobius bucchichi,Subtrop,Yes,Mimicked threat,"Jump distance, bare",Not provided,0.123,1.1309,88.426,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Gobius bucchichi,Subtrop,Yes,Mimicked threat,"Jump distance, turf algae",Not provided,0.1033,1.1088,90.186,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Gobius bucchichi,Subtrop,Yes,Mimicked threat,"Startle distance, bare",Not provided,0.7482,2.1132,47.322,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Gobius bucchichi,Subtrop,Yes,Mimicked threat,"Startle distance, turf algae",Not provided,0.7829,2.1878,45.708,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Forsterygion lapillum,Temp,Yes,Mimicked threat,"Escape speed, bare ",Not provided,0.2735,1.3146,76.071,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Forsterygion lapillum,Temp,Yes,Mimicked threat,"Escape speed, turf algae/rock",Not provided,0.5178,1.6783,59.583,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Forsterygion lapillum,Temp,Yes,Mimicked threat,"Jump distance, bare",Not provided,0.0112,1.0113,98.886,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Forsterygion lapillum,Temp,Yes,Mimicked threat,"Jump distance, turf algae/rock",Not provided,0.1777,1.1945,83.719,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Forsterygion lapillum,Temp,Yes,Mimicked threat,"Startle distance, bare",Not provided,0.4889,1.6305,61.33,
a52,Nagelkerken et al,2015,2016,Ocean acidification alters fish populations indirectly through habitat modification,Nat Clim Change,17.184,19.181,Forsterygion lapillum,Temp,Yes,Mimicked threat,"Startle distance, turf algae/rock",Not provided,0.1276,1.1361,88.021,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,Response latency,Adult,0.1473,1.1587,86.304,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,s1 duration,Adult,0.1153,1.1222,89.11,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,s2 duration,Adult,0.0139,1.014,98.62,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,Turning rate,Adult,0.2298,1.2583,79.469,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,Cumulative distance (D),Adult,0.0619,1.0639,93.998,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,Maximum velocity (Vmax),Adult,0.0932,1.0977,91.101,
a53,Nasuchon et al,2016,2016,Escape responses of the Japanese anchovy Engraulis japonicus under elevated temperature and CO2 conditions,Fish Sci,0.839,0.794,Engraulis japonicus,Temp,Yes,Mimicked threat,Maximum acceleration (Amax),Adult,0.4229,1.5264,65.514,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Sparus aurata,Subtrop,Yes,Food,Time swimming,Larvae,0.3787,1.4604,68.475,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Argyrosomus regius,Subtrop,Yes,Food,Time swimming,Larvae,0.2756,1.3173,75.912,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Sparus aurata,Subtrop,Yes,Food,Attack %,Larvae,1.224,3.4008,29.405,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Argyrosomus regius,Subtrop,Yes,Food,Attack %,Larvae,0.1865,1.205,82.986,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Sparus aurata,Subtrop,Yes,Food,Capture %,Larvae,1.4429,4.233,23.624,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Argyrosomus regius,Subtrop,Yes,Food,Capture %,Larvae,0.8237,2.2789,43.881,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Sparus aurata,Subtrop,Yes,Food,Spin %,Larvae,0,1,100,
a54,Pimentel et al,2016,2016,"Foraging behaviour, swimming performance and malformations of early stages of commercially important fishes under ocean acidification and warming",Clim Change,3.496,3.537,Argyrosomus regius,Subtrop,Yes,Food,Spin %,Larvae,0,1,100,
a55,Rossi et al,2016,2016,Lost at sea: ocean acidification undermines larval fish orientation via altered hearing and marine soundscape modification,Biol Lett,3.089,3.345,Argyrosomus japonicus,Trop,Yes,Auditory,"% time in loud chamber sections, ctrl soundscape",Larvae,0.5521,1.7369,57.574,
a55,Rossi et al,2016,2016,Lost at sea: ocean acidification undermines larval fish orientation via altered hearing and marine soundscape modification,Biol Lett,3.089,3.345,Argyrosomus japonicus,Trop,Yes,Auditory,"% time in loud chamber sections, high co2 soundscapoe",Larvae,0.1345,1.144,87.415,
a55,Rossi et al,2016,2016,Lost at sea: ocean acidification undermines larval fish orientation via altered hearing and marine soundscape modification,Biol Lett,3.089,3.345,Argyrosomus japonicus,Trop,Yes,Auditory,"% time in loud chamber sections, ctrl-ctrl vs co2-co2",Larvae,0.3904,1.4776,67.679,
a56,Sampaio et al,2016,2016,"Habitat selection disruption and lateralization impairment of cryptic flatfish in a warm, acid, and contaminated ocean",Mar Biol,2.136,2.215,Solea senegalensis,Trop,No,null,Absolute lateralization,Juvenile,0.1693,1.1845,84.426,
a56,Sampaio et al,2016,2016,"Habitat selection disruption and lateralization impairment of cryptic flatfish in a warm, acid, and contaminated ocean",Mar Biol,2.136,2.215,Solea senegalensis,Trop,Yes,Habitat,Time in simple habitat,Juvenile,0.2845,1.3291,75.239,
a57,Silva et al,2016,2016,"Effects of ocean acidification on the swimming ability, development and biochemical responses of sand smelt larvae",Sci Tot Environ,4.9,4.61,Atherina presbyter,Subtrop,No,null,Swim speed,Larvae,0.0611,1.063,94.073,
a57,Silva et al,2016,2016,"Effects of ocean acidification on the swimming ability, development and biochemical responses of sand smelt larvae",Sci Tot Environ,4.9,4.61,Atherina presbyter,Subtrop,No,null,Swim speed,Larvae,0.0136,1.0137,98.649,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,No,null,"Absolute lateralization, 9 days acclimation water",Juvenile,0.2666,1.3055,76.598,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,No,null,"Absolute lateralization, 19 days, acclimation water",Juvenile,0.585,1.795,55.711,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,No,null,"Absolute lateralization, 21 days, control water",Juvenile,0.1241,1.1321,88.329,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,No,null,Prop time swimming,Juvenile,0.0158,1.0159,98.432,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,No,null,Swimming distance,Juvenile,0.2482,1.2817,78.02,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,Yes,Prey,% time in prey cue,Juvenile,0.1788,1.1958,83.627,
a58,Sundin & Jutfelt,2015,2016,9–28 d of exposure to elevated pCO2 reduces avoidance of predator odour but had no effect on behavioural lateralization or swimming activity in a temperate wrasse (Ctenolabrus rupestris),ICES J Mar Sci,2.626,2.906,Ctenolabrus rupestris,Temp,Yes,Predator,% time in predator cue,Juvenile,0.0021,1.0021,99.79,
a59,Allan et al,2017,2017,Warming has a greater effect than elevated CO2 on predator–prey interactions in coral reef fish,Proc R Soc B,4.847,4.847,Pomacentrus wardi,Trop,Yes,Predator,Apparent looming threshold,Larvae,0.9158,2.4988,40.02,
a59,Allan et al,2017,2017,Warming has a greater effect than elevated CO2 on predator–prey interactions in coral reef fish,Proc R Soc B,4.847,4.847,Pomacentrus wardi,Trop,Yes,Predator,Escape distance,Larvae,0.0264,1.0268,97.395,
a59,Allan et al,2017,2017,Warming has a greater effect than elevated CO2 on predator–prey interactions in coral reef fish,Proc R Soc B,4.847,4.847,Pomacentrus wardi,Trop,Yes,Predator,Escape speed,Larvae,0.2286,1.2568,79.565,
a59,Allan et al,2017,2017,Warming has a greater effect than elevated CO2 on predator–prey interactions in coral reef fish,Proc R Soc B,4.847,4.847,Pomacentrus wardi,Trop,Yes,Predator,Reaction distance,Larvae,0.076,1.079,92.682,
a59,Allan et al,2017,2017,Warming has a greater effect than elevated CO2 on predator–prey interactions in coral reef fish,Proc R Soc B,4.847,4.847,Pseudochromis fuscus,Trop,Yes,Prey,Attack rate,Larvae,0.2965,1.3451,74.342,
a59,Allan et al,2017,2017,Warming has a greater effect than elevated CO2 on predator–prey interactions in coral reef fish,Proc R Soc B,4.847,4.847,Pseudochromis fuscus,Trop,Yes,Prey,Predation rate,Larvae,2.7175,15.1424,6.604,
a60,Castro et al,2017,2017,Painted Goby Larvae under High-CO2 Fail to Recognize Reef Sounds,PloS One,2.766,2.766,Pomatoschistus pictus,Temp,Yes,Auditory,"% time in reef recording, Fig 3",Larvae,1.0504,2.8588,34.98,
a60,Castro et al,2017,2017,Painted Goby Larvae under High-CO2 Fail to Recognize Reef Sounds,PloS One,2.766,2.766,Pomatoschistus pictus,Temp,Yes,Auditory,"% time in reef recording, Fig 4",Larvae,0.5452,1.725,57.973,
a60,Castro et al,2017,2017,Painted Goby Larvae under High-CO2 Fail to Recognize Reef Sounds,PloS One,2.766,2.766,Pomatoschistus pictus,Temp,Yes,Auditory,"% time in offshore recording, Fig 5",Larvae,0.0251,1.0254,97.521,
a61,Cattano et al,2017,2017,Ocean acidification does not impair predator recognition but increases juvenile growth in a temperate wrasse off CO2 seeps,Mar Env Res,3.159,3.159,Symphodus ocellatus,Subtrop,Yes,Predator,"% time in predator cue, Fig 3",Larvae,0.2405,1.2719,78.623,
a61,Cattano et al,2017,2017,Ocean acidification does not impair predator recognition but increases juvenile growth in a temperate wrasse off CO2 seeps,Mar Env Res,3.159,3.159,Symphodus ocellatus,Subtrop,Yes,Predator,"prop time in predator cue, Fig 4",Larvae,0.012,1.0121,98.807,
a62,Ferrari et al ,2017,2017,Predation in High CO2 Waters: Prey Fish from High-Risk Environments are Less Susceptible to Ocean Acidification,Integr Comp Biol,2.751,2.751,Pomacentrus amboinensis,Trop,Yes,Prey,"Feeding strikes, low risk",Juvenile,0.2231,1.2499,80.003,
a62,Ferrari et al ,2017,2017,Predation in High CO2 Waters: Prey Fish from High-Risk Environments are Less Susceptible to Ocean Acidification,Integr Comp Biol,2.751,2.751,Pomacentrus amboinensis,Trop,Yes,Prey+ Predator,"Feeding strikes, high risk",Juvenile,0.1448,1.1558,86.52,
a62,Ferrari et al ,2017,2017,Predation in High CO2 Waters: Prey Fish from High-Risk Environments are Less Susceptible to Ocean Acidification,Integr Comp Biol,2.751,2.751,Pomacentrus amboinensis,Trop,Yes,Prey,"Distance ventured, low risk",Juvenile,0.2995,1.3492,74.119,
a62,Ferrari et al ,2017,2017,Predation in High CO2 Waters: Prey Fish from High-Risk Environments are Less Susceptible to Ocean Acidification,Integr Comp Biol,2.751,2.751,Pomacentrus amboinensis,Trop,Yes,Prey+ Predator,"Distance ventured, high risk",Juvenile,0.2435,1.2757,78.388,
a62,Ferrari et al ,2017,2017,Predation in High CO2 Waters: Prey Fish from High-Risk Environments are Less Susceptible to Ocean Acidification,Integr Comp Biol,2.751,2.751,Pomacentrus amboinensis,Trop,Yes,Prey,"Boldness, low risk",Juvenile,0.0683,1.0707,93.398,
a62,Ferrari et al ,2017,2017,Predation in High CO2 Waters: Prey Fish from High-Risk Environments are Less Susceptible to Ocean Acidification,Integr Comp Biol,2.751,2.751,Pomacentrus amboinensis,Trop,Yes,Prey+ Predator,"Boldness, high risk",Juvenile,0.139,1.1491,87.023,
a63,Goldenberg et al,2017,2017,Boosted food web productivity through ocean acidification collapses under warming,Glob Change Biol,8.997,8.997,Favonigobius lateralis,Temp,Yes,Prey,"Food search activity, absence",Adult,0.3119,1.366,73.205,
a63,Goldenberg et al,2017,2017,Boosted food web productivity through ocean acidification collapses under warming,Glob Change Biol,8.997,8.997,Favonigobius lateralis,Temp,Yes,Prey,"Food search activity, presence",Adult,0.8651,2.3752,42.101,
a63,Goldenberg et al,2017,2017,Boosted food web productivity through ocean acidification collapses under warming,Glob Change Biol,8.997,8.997,Favonigobius lateralis,Temp,Yes,Prey,Predation rate,Adult,0.1122,1.1187,89.387,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 1, 1000 uatm ",Juvenile,0.6217,1.8621,53.703,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 1, 1000 +- 300 uatm",Juvenile,0.2754,1.3171,75.927,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 1, 1000 +- 500 uatm",Juvenile,0.0972,1.1021,90.737,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, Fig 1, 1000 uatm",Juvenile,2.4486,11.5721,8.641,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, Fig 1, 1000 +- 300 uatm",Juvenile,1.6917,5.4287,18.421,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, Fig 1, 1000 +- 500 uatm",Juvenile,1.7918,6.0002,16.666,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 2, 750 uatm",Juvenile,0.4855,1.625,61.539,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 2, 700 +- 300 uatm",Juvenile,0.0968,1.1016,90.774,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 2, 1000 uatm",Juvenile,0.5108,1.6666,60.002,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,"Absolute lateralization, Fig 2, 1000 +- 300 uatm",Juvenile,0.4608,1.5853,63.078,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, Fig 2, 750 uatm",Juvenile,0.6391,1.8948,52.777,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, Fig 2, 750 +- 300 uatm",Juvenile,0.3137,1.3685,73.074,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 1000 uatm",Juvenile,1.1665,3.2107,31.146,
a64,Jarrold et al,2017,2017,Diel CO2 cycles reduce severity of behavioural abnormalities in coral reef fish under ocean acidification,Sci Rep,4.122,4.122,Amphiprion percula,Trop,Yes,Predator,"% time in cue, 1000 +- 300 uatm",Juvenile,0.7445,2.1054,47.497,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Light,"Fig 1, Time in dark zone, stable, January",Juvenile,0.0792,1.0824,92.386,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Light,"Fig 1, Time in dark zone, oscillating, January",Juvenile,0.009,1.009,99.104,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Light,"Fig 1, Time in dark zone, stable, September",Juvenile,0.0399,1.0407,96.089,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Light,"Fig 1, Time in dark zone, oscillating, September",Juvenile,0.0075,1.0075,99.253,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Kin,"Fig 2, Time near walls, stable",Juvenile,0.1834,1.2013,83.244,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Kin,"Fig 2, Time near walls, oscillating",Juvenile,0.0212,1.0214,97.902,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Kin,"Fig 2, Inter-individual distance, stable",Juvenile,0.011,1.0111,98.906,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Kin,"Fig 2, Inter-individual distance, oscillating",Juvenile,0.0676,1.0699,93.463,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Novel object + kin,"Fig 3, Time near object, stable",Juvenile,0.0167,1.0168,98.344,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Novel object + kin,"Fig 3, Time near object, oscillating",Juvenile,0.0594,1.0612,94.233,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Kin,"Fig 3, Inter-individual distance, stable",Juvenile,0.1032,1.1087,90.195,
a65,Kwan et al,2017,2017,CO2-induced ocean acidification does not affect individual or group behaviour in a temperate damselfish,R Soc Open Sci,2.504,2.504,Chromis punctipinnis,Subtrop,Yes,Kin,"Fig 3, Inter-individual distance, oscillating",Juvenile,0.0581,1.0598,94.356,
a66,Pistevos et al,2016,2017,Ocean acidification alters temperature and salinity preferences in larval fish,Oecologia,3.13,3.127,Lates calcarifer,Trop,Yes,Physical Seawater,% time in warm water,Larvae,0.2229,1.2497,80.019,
a66,Pistevos et al,2016,2017,Ocean acidification alters temperature and salinity preferences in larval fish,Oecologia,3.13,3.127,Lates calcarifer,Trop,Yes,Physical Seawater,% time in lower salinity water,Larvae,0.5239,1.6886,59.221,
a66,Pistevos et al,2016,2017,Ocean acidification alters temperature and salinity preferences in larval fish,Oecologia,3.13,3.127,Lates calcarifer,Trop,Yes,Physical Seawater,% time in estuary cue,Larvae,0.2763,1.3182,75.859,
a67,Pistevos et al,2016,2017,Antagonistic effects of ocean acidification and warming on hunting sharks,Oikos,4.03,3.709,Heterodontus portusjacksoni,Subtrop,Yes,Prey,% time spent in prey zone,Larvae,0.3716,1.4501,68.963,
a67,Pistevos et al,2016,2017,Antagonistic effects of ocean acidification and warming on hunting sharks,Oikos,4.03,3.709,Heterodontus portusjacksoni,Subtrop,Yes,Prey,Total distance,Larvae,0.0991,1.1042,90.565,
a67,Pistevos et al,2016,2017,Antagonistic effects of ocean acidification and warming on hunting sharks,Oikos,4.03,3.709,Heterodontus portusjacksoni,Subtrop,Yes,Prey,Time to accept food,Larvae,0.8694,2.3855,41.92,
a68,Schmidt et al,2017,2017,"Impact of ocean warming and acidification on the behaviour of two co-occurring gadid species, Boreogadus saida and Gadus morhua, from Svalbard",Mar Ecol Prog Ser,2.276,2.276,Boreogadus saida,Polar,No,null,Spontaneous activity,Juvenile,0.1411,1.1515,86.84,
a68,Schmidt et al,2017,2017,"Impact of ocean warming and acidification on the behaviour of two co-occurring gadid species, Boreogadus saida and Gadus morhua, from Svalbard",Mar Ecol Prog Ser,2.276,2.276,Boreogadus saida,Polar,No,null,Absolute lateralization,Juvenile,0.2741,1.3153,76.026,
a68,Schmidt et al,2017,2017,"Impact of ocean warming and acidification on the behaviour of two co-occurring gadid species, Boreogadus saida and Gadus morhua, from Svalbard",Mar Ecol Prog Ser,2.276,2.276,Gadus morhua,Polar,No,null,Spontaneous activity,Juvenile,0.0235,1.0238,97.677,
a68,Schmidt et al,2017,2017,"Impact of ocean warming and acidification on the behaviour of two co-occurring gadid species, Boreogadus saida and Gadus morhua, from Svalbard",Mar Ecol Prog Ser,2.276,2.276,Gadus morhua,Polar,No,null,Absolute lateralization,Juvenile,0.1692,1.1844,84.434,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate + habitat,"Time zig-zag, female in cylinder",Adult,0.2705,1.3106,76.3,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate + habitat,"Time fanning, female in cylinder",Adult,0.1934,1.2134,82.415,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate + habitat,"# leads to nest, female in cylinder",Adult,0.0946,1.0992,90.974,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate + habitat,"# times gluing on nest, female in cylinder",Adult,0.1271,1.1355,88.065,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Habitat,"Time zig-zag, female free",Adult,1.9965,7.3632,13.581,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Habitat,"Time fanning, female free",Adult,1.2142,3.3676,29.695,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Habitat,"# leads to nest, female free",Adult,0.4937,1.6384,61.036,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Habitat,"# times gluing on nest, female free",Adult,0.2657,1.3043,76.667,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate,Latency until first mating attempt,Adult,0.4628,1.5885,62.952,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate,Latency until successful mating,Adult,0.1178,1.125,88.887,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate,Mating duration,Adult,0.0753,1.0782,92.747,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate,Number of bites at female,Adult,0.5097,1.6648,60.068,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Mate,Number of mating attempts,Adult,0.9174,2.5028,39.956,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 2",Adult,0.1443,1.1552,86.563,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 3",Adult,0.0023,1.0023,99.77,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 4",Adult,0.0195,1.0197,98.069,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 5",Adult,0.0821,1.0856,92.118,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 6",Adult,0.1277,1.1362,88.012,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 7",Adult,0.2584,1.2949,77.229,
a69,Sundin et al,2017,2017,No effect of elevated carbon dioxide on reproductive behaviors in the three-spined stickleback,Behav Ecol,3.347,3.347,Gasterosteus aculeatus,Subtrop,Yes,Offspring (kin),"Fanning, day 8",Adult,0.1914,1.2109,82.58,
a70,Sundin et al,2017,2017,Long-term exposure to elevated carbon dioxide does not alter activity levels of a coral reef fish in response to predator chemical cues,Behav Ecol & Sociobiol,2.473,2.473,Acanthochromis polyacanthus,Trop,No,null,Mean swimming duration,Juvenile,0.0898,1.094,91.411,
a70,Sundin et al,2017,2017,Long-term exposure to elevated carbon dioxide does not alter activity levels of a coral reef fish in response to predator chemical cues,Behav Ecol & Sociobiol,2.473,2.473,Acanthochromis polyacanthus,Trop,No,null,Mean swimming distance,Juvenile,0.0496,1.0509,95.161,
a70,Sundin et al,2017,2017,Long-term exposure to elevated carbon dioxide does not alter activity levels of a coral reef fish in response to predator chemical cues,Behav Ecol & Sociobiol,2.473,2.473,Acanthochromis polyacanthus,Trop,No,null,"Change in swim duration, sham",Juvenile,NA,NA,NA,
a70,Sundin et al,2017,2017,Long-term exposure to elevated carbon dioxide does not alter activity levels of a coral reef fish in response to predator chemical cues,Behav Ecol & Sociobiol,2.473,2.473,Acanthochromis polyacanthus,Trop,No,null,"Change in swim distance, sham",Juvenile,NA,NA,NA,
a70,Sundin et al,2017,2017,Long-term exposure to elevated carbon dioxide does not alter activity levels of a coral reef fish in response to predator chemical cues,Behav Ecol & Sociobiol,2.473,2.473,Acanthochromis polyacanthus,Trop,Yes,Predator,"Change in swim duration, predator",Juvenile,0.1574,1.1705,85.436,
a70,Sundin et al,2017,2017,Long-term exposure to elevated carbon dioxide does not alter activity levels of a coral reef fish in response to predator chemical cues,Behav Ecol & Sociobiol,2.473,2.473,Acanthochromis polyacanthus,Trop,Yes,Predator,"Change in swim distance, predator",Juvenile,0.383,1.4667,68.181,
a71,Welch & Munday,2017,2017,Heritability of behavioural tolerance to high CO2 in a coral reef fish is masked by nonadaptive phenotypic plasticity,Evol Appl,4.694,4.694,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in CAC, control fathers, MARFU (lab), acute",Larvae,0.7175,2.0493,48.797,
a71,Welch & Munday,2017,2017,Heritability of behavioural tolerance to high CO2 in a coral reef fish is masked by nonadaptive phenotypic plasticity,Evol Appl,4.694,4.694,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in CAC, control fathers, MARFU (lab), chronic",Larvae,0.9427,2.5669,38.957,
a71,Welch & Munday,2017,2017,Heritability of behavioural tolerance to high CO2 in a coral reef fish is masked by nonadaptive phenotypic plasticity,Evol Appl,4.694,4.694,Acanthochromis polyacanthus,Trop,Yes,Predator,"% time in CAC, contol fathers, LIRS (field), acute",Larvae,0.8067,2.2405,44.633,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,null,"New area explored, 1 week, seawater cue",Juvenile,0.2111,1.235,80.969,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,null,"New area explored, 3 weeks, seawater cue",Juvenile,0.2096,1.2332,81.091,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,null,"Activity (lines crossed), 1 week, seawater cue",Juvenile,0.1234,1.1313,88.391,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,null,"Activity (lines crossed), 3 weeks, seawater cue",Juvenile,0.0337,1.0343,96.686,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,Predator,"New area explored, 1 week, alarm cue",Juvenile,0.095,1.0997,90.937,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,Predator,"New area explored, 3 weeks, alarm cue",Juvenile,0.1896,1.2088,82.729,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,Predator,"Activity (lines crossed), 1 week, alarm cue",Juvenile,0.1061,1.1119,89.933,
a72,Davis et al,2018,2018,Juvenile rockfish show resilience to CO2- acidification and hypoxia across multiple biological scales,Conserv Physiol,3.46,3.46,Sebastes spp.,Trop,Yes,Predator,"Activity (lines crossed), 3 weeks, alarm cue",Juvenile,0.0019,1.0019,99.81,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Light,"% time in dark zone, Mid CO2",Juvenile,0.0219,1.0221,97.834,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Light,"% time in dark zone, High CO2",Juvenile,0.1475,1.1589,86.286,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time active, Mid CO2, 7 days",Juvenile,0.094,1.0986,91.028,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time active, High CO2, 7 days",Juvenile,0.0222,1.0224,97.804,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time active, Mid CO2, 14 days",Juvenile,0.0569,1.0585,94.469,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time active, High CO2, 14 days",Juvenile,0.072,1.0747,93.053,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in center zone, Mid CO2, 7 days, Fig S1",Juvenile,0.1653,1.1797,84.764,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in center zone, High CO2, 7 days, Fig S1",Juvenile,0.3232,1.3815,72.383,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in center zone, Mid CO2, 14 days, Fig S1",Juvenile,0.0553,1.0569,94.62,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in center zone, High CO2, 14 days, Fig S1",Juvenile,0.6206,1.86,53.762,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in center zone, Mid CO2, 7 days, Fig S2",Juvenile,0.3847,1.4692,68.065,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in center zone, High CO2, 7 days, Fig S2",Juvenile,0.2573,1.2934,77.314,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in center zone, Mid CO2, 14 days, Fig S2",Juvenile,0.1823,1.2,83.335,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in center zone, High CO2, 14 days, Fig S2",Juvenile,0.4902,1.6326,61.25,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in middle zone, Mid CO2, 7 days, Fig S2",Juvenile,0.0819,1.0853,92.136,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in middle zone, High CO2, 7 days, Fig S2",Juvenile,0.0763,1.0793,92.654,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in middle zone, Mid CO2, 14 days, Fig S2",Juvenile,0.041,1.0419,95.983,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"% time in middle zone, High CO2, 14 days, Fig S2",Juvenile,0.2242,1.2513,79.916,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in thigmotaxic zone, Mid CO2, 7 days, Fig S1",Juvenile,0.2603,1.2973,77.082,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in thigmotaxic zone, High CO2, 7 days, Fig S1",Juvenile,0.1733,1.1892,84.089,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in thigmotaxic zone, Mid CO2, 14 days, Fig S1",Juvenile,0.36,1.4333,69.768,
a73,Davis et al,2017,2018,Antarctic emerald rockcod have the capacity to compensate for warming when uncoupled from CO2-acidification,Glob Change Biol,8.997,8.997,Trematomus bernacchii,Polar,Yes,Novel object,"Time in thigmotaxic zone, High CO2, 14 days, Fig S1",Juvenile,0.2058,1.2285,81.4,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,Yes,Prey,Visual cue attraction,Not provided,0.5153,1.6741,59.732,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,Yes,Prey,Olfactory cue attraction,Not provided,0.441,1.5543,64.339,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,Yes,Prey,Multiple sense cue attraction,Not provided,0.1342,1.1436,87.442,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,Yes,Prey,Hunting success,Not provided,0.2153,1.2402,80.63,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,Yes,Prey,Feeding activity,Not provided,0.1206,1.1282,88.639,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,No,null,"Risk taking (density-stndardized), no predator",Not provided,0.0795,1.0827,92.358,
a74,Goldenberg et al,2018,2018,Ecological complexity buffers the impacts of future climate on marine consumers,Nat Clim Change,19.181,19.181,Not provided,Not provided,Yes,Predator,"Risk taking (density-stndardized), predator",Not provided,0.5186,1.6797,59.535,
a75,Laubenstein et al,2018,2018,Correlated Effects of Ocean Acidification and Warming on Behavioral and Metabolic Traits of a Large Pelagic Fish,Diversity,-,-,Seriola lalandi,Subtrop,No,null,Escape distance (distance traveled),Larvae,0.1002,1.1054,90.466,
a75,Laubenstein et al,2018,2018,Correlated Effects of Ocean Acidification and Warming on Behavioral and Metabolic Traits of a Large Pelagic Fish,Diversity,-,-,Seriola lalandi,Subtrop,No,null,Escape speed (average velocity),Larvae,0.009,1.009,99.104,
a75,Laubenstein et al,2018,2018,Correlated Effects of Ocean Acidification and Warming on Behavioral and Metabolic Traits of a Large Pelagic Fish,Diversity,-,-,Seriola lalandi,Subtrop,No,null,Time spent in inner zone,Larvae,0.2543,1.2896,77.546,
a75,Laubenstein et al,2018,2018,Correlated Effects of Ocean Acidification and Warming on Behavioral and Metabolic Traits of a Large Pelagic Fish,Diversity,-,-,Seriola lalandi,Subtrop,No,null,Time active,Larvae,0.0663,1.0685,93.585,
a76,Maulvault et al,2018,2018,"Differential behavioural responses to venlafaxine exposure route, warming and acidification in juvenile fish (Argyrosomus regius)",Sci Tot Environ,4.61,4.61,Argyrosomus regius,Subtrop,Yes,Kin,Latency to top,Juvenile,0.1372,1.1471,87.18,
a76,Maulvault et al,2018,2018,"Differential behavioural responses to venlafaxine exposure route, warming and acidification in juvenile fish (Argyrosomus regius)",Sci Tot Environ,4.61,4.61,Argyrosomus regius,Subtrop,Yes,Kin,Time at top,Juvenile,0.8242,2.2801,43.859,
a76,Maulvault et al,2018,2018,"Differential behavioural responses to venlafaxine exposure route, warming and acidification in juvenile fish (Argyrosomus regius)",Sci Tot Environ,4.61,4.61,Argyrosomus regius,Subtrop,Yes,Kin,Latency to move toward shoal,Juvenile,0.0607,1.0626,94.111,
a76,Maulvault et al,2018,2018,"Differential behavioural responses to venlafaxine exposure route, warming and acidification in juvenile fish (Argyrosomus regius)",Sci Tot Environ,4.61,4.61,Argyrosomus regius,Subtrop,Yes,Kin,Transistions toward shoal,Juvenile,0.0645,1.0666,93.754,
a76,Maulvault et al,2018,2018,"Differential behavioural responses to venlafaxine exposure route, warming and acidification in juvenile fish (Argyrosomus regius)",Sci Tot Environ,4.61,4.61,Argyrosomus regius,Subtrop,Yes,Kin,% time with shoal,Juvenile,0.3655,1.4412,69.385,
a76,Maulvault et al,2018,2018,"Differential behavioural responses to venlafaxine exposure route, warming and acidification in juvenile fish (Argyrosomus regius)",Sci Tot Environ,4.61,4.61,Argyrosomus regius,Subtrop,No,null,Absolute lateralization,Juvenile,0.6412,1.8988,52.666,
a77,McCormick et al,2018,2018,Effect of elevated CO2 and small boat noise on the kinematics of predator–prey interactions,Proc R Soc B,4.847,4.847,Pseudochromis fuscus,Trop,Yes,Prey,Attack rate,Adult,1.3393,3.8164,26.203,
a77,McCormick et al,2018,2018,Effect of elevated CO2 and small boat noise on the kinematics of predator–prey interactions,Proc R Soc B,4.847,4.847,Pseudochromis fuscus,Trop,Yes,Prey,Attack distance,Adult,0.3403,1.4054,71.156,
a77,McCormick et al,2018,2018,Effect of elevated CO2 and small boat noise on the kinematics of predator–prey interactions,Proc R Soc B,4.847,4.847,Pseudochromis fuscus,Trop,Yes,Prey,Attack speed,Adult,0.6148,1.8493,54.075,
a77,McCormick et al,2018,2018,Effect of elevated CO2 and small boat noise on the kinematics of predator–prey interactions,Proc R Soc B,4.847,4.847,Pseudochromis fuscus,Trop,Yes,Prey,Apparent looming threshold,Adult,1.2417,3.4615,28.889,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Average feeding strikes,high food, ctrl/ctrl vs. ctrl/CO2",Juvenile,0.0235,1.0238,97.677,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Average feeding strikes, low food, , ctrl/ctrl vs. ctrl/CO2",Juvenile,0.06,1.0618,94.176,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Average feeding strikes,high food, , ctrl/ctrl vs. CO2/CO2",Juvenile,0.1354,1.145,87.337,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Average feeding strikes, low food, , ctrl/ctrl vs. CO2/CO2",Juvenile,0.0145,1.0146,98.56,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, seawater, high food, , ctrl/ctrl vs. ctrl/CO2",Juvenile,0.066,1.0682,93.613,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, seawater, low food, , ctrl/ctrl vs. ctrl/CO2",Juvenile,0.0518,1.0532,94.952,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, seawater, high food, , ctrl/ctrl vs. CO2/CO2",Juvenile,0.0787,1.0819,92.432,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, seawater, low food, , ctrl/ctrl vs. CO2/CO2",Juvenile,0.0729,1.0756,92.969,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, predator, high food, , ctrl/ctrl vs. ctrl/CO2",Juvenile,1.3924,4.0245,24.848,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, predator, low food, , ctrl/ctrl vs. ctrl/CO2",Juvenile,1.1149,3.0493,32.795,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, predator, high food, , ctrl/ctrl vs. CO2/CO2",Juvenile,1.3571,3.8849,25.741,
a78,McMahon et al,2018,2018,Food ration does not influence the effect of elevated CO2 on antipredator behaviour of a reef fish,Mar Ecol Prog Ser,2.276,2.276,Amphiprion percula,Trop,Yes,Food,"Change feeding strikes, predator, low food, , ctrl/ctrl vs. CO2/CO2",Juvenile,1.0976,2.997,33.367,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,No,null,"Baseline activity, 2 days",Juvenile,0.0703,1.0728,93.211,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,No,null,"Baseline activity, 7 days",Juvenile,0.3445,1.4113,70.857,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,No,null,"Baseline activity, 14 days",Juvenile,0.5266,1.6932,59.061,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,No,null,"Time spent freezing, before pred, 7 days",Juvenile,0.4336,1.5428,64.817,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,No,null,"Time spent freezing, before pred, 2 days",Juvenile,1.0143,2.7574,36.266,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,No,null,"Time spent freezing, before pred, 7 days",Juvenile,1.3717,3.942,25.368,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,Yes,Predator,"Time spent freezing, w/ pred, 2 days",Juvenile,0.2823,1.3262,75.405,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,Yes,Predator,"Time spent freezing, w/ pred, 7 days",Juvenile,0.7379,2.0915,47.812,
a79,Porteus et al,2018,2018,Near-future CO2 levels impair the olfactory system of a marine fish,Nat Clim Change,19.181,19.181,Dicentrarchus labrax,Subtrop,Yes,Predator,"Time spent freezing, w/ pred, 14 days",Juvenile,1.0957,2.9913,33.431,
a80,Raby et al,2018,2018,Exposure to elevated carbon dioxide does not impair shortterm swimming behaviour or shelter-seeking in a predatory coral-reef fish,J Fish Biol,1.702,1.702,Cephalopholis cyanostigma,Trop,Yes,Habitat,Immobile at surface,Adult,0,1,100,
a80,Raby et al,2018,2018,Exposure to elevated carbon dioxide does not impair shortterm swimming behaviour or shelter-seeking in a predatory coral-reef fish,J Fish Biol,1.702,1.702,Cephalopholis cyanostigma,Trop,Yes,Habitat,Time to ocean floor,Adult,0.0505,1.0518,95.075,
a80,Raby et al,2018,2018,Exposure to elevated carbon dioxide does not impair shortterm swimming behaviour or shelter-seeking in a predatory coral-reef fish,J Fish Biol,1.702,1.702,Cephalopholis cyanostigma,Trop,Yes,Habitat,Time to shelter,Adult,0.3506,1.4199,70.427,
a80,Raby et al,2018,2018,Exposure to elevated carbon dioxide does not impair shortterm swimming behaviour or shelter-seeking in a predatory coral-reef fish,J Fish Biol,1.702,1.702,Cephalopholis cyanostigma,Trop,Yes,Habitat,Time immobile,Adult,0.034,1.0346,96.657,
a80,Raby et al,2018,2018,Exposure to elevated carbon dioxide does not impair shortterm swimming behaviour or shelter-seeking in a predatory coral-reef fish,J Fish Biol,1.702,1.702,Cephalopholis cyanostigma,Trop,Yes,Habitat,Opercular beats,Adult,0.0078,1.0078,99.223,
a80,Raby et al,2018,2018,Exposure to elevated carbon dioxide does not impair shortterm swimming behaviour or shelter-seeking in a predatory coral-reef fish,J Fish Biol,1.702,1.702,Cephalopholis cyanostigma,Trop,Yes,Habitat,Tail beats,Adult,0.0513,1.0526,94.999,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time hiding, 4 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,1.2534,3.5022,28.553,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time hiding, 8 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,0.7537,2.1248,47.062,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time hiding, 12 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,10.1338,25179.8664,0.004,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time swimming, 4 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,0.268,1.3073,76.491,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time swimming, 8 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,0.1061,1.1119,89.933,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time swimming, 12 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,0.5995,1.8212,54.909,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time floating, 4 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,1.8326,6.2501,16,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time floating, 8 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,0.6445,1.905,52.492,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time floating, 12 weeks, ctrl/ctrl vs ctrl/OA",Juvenile,13.0411,460975.4192,0,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time hiding, 4 weeks, ctrl/ctrl vs OA/OA",Juvenile,1.0498,2.8571,35.001,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time hiding, 8 weeks, ctrl/ctrl vs OA/OA",Juvenile,0.1372,1.1471,87.18,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time hiding, 12 weeks, ctrl/ctrl vs OA/OA",Juvenile,11.9721,158276.6927,0.001,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time swimming, 4 weeks, ctrl/ctrl vs OA/OA",Juvenile,0.0919,1.0963,91.22,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time swimming, 8 weeks, ctrl/ctrl vs OA/OA",Juvenile,0.2855,1.3304,75.164,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time swimming, 12 weeks, ctrl/ctrl vs OA/OA",Juvenile,1.2106,3.3555,29.802,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time floating, 4 weeks, ctrl/ctrl vs OA/OA",Juvenile,0.0286,1.029,97.181,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time floating, 8 weeks, ctrl/ctrl vs OA/OA",Juvenile,0.3998,1.4915,67.045,
a81,Rodriguez-Dominguez et al,2018,2018,Irreversible behavioural impairment of fish starts early: Embryonic exposure to ocean acidification,Mar Poll Bull,3.241,3.241,Vincentia badia,Temp,Yes,Shelter,"% time floating, 12 weeks, ctrl/ctrl vs OA/OA",Juvenile,0.3795,1.4616,68.42,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - estuary, 16 dph",Larvae,0.8596,2.3622,42.333,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - estuary, 18 dph",Larvae,0.3806,1.4632,68.345,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - estuary, 19 dph",Larvae,0.1764,1.1929,83.828,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - estuary, 20 dph",Larvae,0.0505,1.0518,95.075,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - estuary, 21 dph",Larvae,0.0384,1.0391,96.233,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - reef, 16 dph",Larvae,0.1318,1.1409,87.652,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - reef, 17 dph",Larvae,0,1,100,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - reef, 18 dph",Larvae,0.0563,1.0579,94.526,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - reef, 19 dph",Larvae,0.0513,1.0526,94.999,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - reef, 20 dph",Larvae,0.0776,1.0807,92.533,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - reef, 21 dph",Larvae,0.0435,1.0445,95.743,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 13 dph",Larvae,0.7538,2.1251,47.057,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 14 dph",Larvae,0.3017,1.3522,73.956,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 15 dph",Larvae,0.1395,1.1497,86.979,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 16 dph",Larvae,0.1656,1.1801,84.739,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 18 dph",Larvae,0.1449,1.1559,86.511,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 19 dph",Larvae,0.1474,1.1588,86.295,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,% time near speaker - white noise. 20 dph,Larvae,0.168,1.1829,84.535,
a82,Rossi et al,2018,2018,On the wrong track: ocean acidification attracts larval fish to irrelevant environmental cues,Sci Rep,4.122,4.122,Lates calcarifer,Trop,Yes,Auditory,"% time near speaker - white noise, 21 dph",Larvae,0.3257,1.385,72.202,
a83,Sswat et al,2018,2018,"Growth performance and survival of larval Atlantic herring, under the combined effects of elevated temperatures and CO2",PloS One,2.766,2.766,Clupea harengus,Temp,No,null,"Mean activity (size standardized), 28 days",Larvae,0.0507,1.052,95.056,
a83,Sswat et al,2018,2018,"Growth performance and survival of larval Atlantic herring, under the combined effects of elevated temperatures and CO2",PloS One,2.766,2.766,Clupea harengus,Temp,No,null,"Mean activity (size standardized), 30 days",Larvae,0.2611,1.2984,77.02,
a84,Sundin & Jutfelt,2018,2018,Effects of elevated carbon dioxide on male and female behavioural lateralization in a temperate goby,R Soc Open Sci,2.504,2.504,Gobiusculus flavescens,Temp,No,null,"Absolute lateralization, Year 1, female",Adult,0,1,100,
a84,Sundin & Jutfelt,2018,2018,Effects of elevated carbon dioxide on male and female behavioural lateralization in a temperate goby,R Soc Open Sci,2.504,2.504,Gobiusculus flavescens,Temp,No,null,"Absolute lateralization, Year 1, male",Adult,0.0322,1.0327,96.831,
a84,Sundin & Jutfelt,2018,2018,Effects of elevated carbon dioxide on male and female behavioural lateralization in a temperate goby,R Soc Open Sci,2.504,2.504,Gobiusculus flavescens,Temp,No,null,"Absolute lateralization, Year 2, female",Adult,0.2901,1.3366,74.819,
a84,Sundin & Jutfelt,2018,2018,Effects of elevated carbon dioxide on male and female behavioural lateralization in a temperate goby,R Soc Open Sci,2.504,2.504,Gobiusculus flavescens,Temp,No,null,"Absolute lateralization, Year 2, male",Adult,0.2433,1.2755,78.404,
a85,Watson et al,2018,2018,Ocean warming has a greater effect than acidification on the early life history development and swimming performance of a large circumglobal pelagic fish,Glob Change Biol,8.997,8.997,Seriola lalandi,Subtrop,Yes,Mimicked threat,Escape distance,Juvenile,0.0522,1.0536,94.914,
a85,Watson et al,2018,2018,Ocean warming has a greater effect than acidification on the early life history development and swimming performance of a large circumglobal pelagic fish,Glob Change Biol,8.997,8.997,Seriola lalandi,Subtrop,Yes,Mimicked threat,Escape speed,Juvenile,0.0434,1.0444,95.753,
a85,Watson et al,2018,2018,Ocean warming has a greater effect than acidification on the early life history development and swimming performance of a large circumglobal pelagic fish,Glob Change Biol,8.997,8.997,Seriola lalandi,Subtrop,Yes,Mimicked threat,Response latency,Juvenile,0.1551,1.1678,85.633,
a86,Steckbauer et al,2018,2018,Predator avoidance in the European seabass after recovery from short-term hypoxia and different CO2 conditions,Front Mar Sci,-,-,Dicentrachus labrax,Temp,Yes,Predator,Time swimming toward refuge,Juvenile,1.4242,4.1545,24.07,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, baseline, pre, Mid CO2",Juvenile,0.1307,1.1396,87.748,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, baseline, pre, High CO2",Juvenile,0.5138,1.6716,59.822,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, baseline, cue, Mid CO2",Juvenile,0.1535,1.1659,85.77,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, baseline, cue, High CO2",Juvenile,0.1583,1.1715,85.359,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, baseline, feed, Mid CO2",Juvenile,0.2583,1.2947,77.236,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, baseline, feed, High CO2",Juvenile,0.2583,1.2947,77.236,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, baseline, post, Mid CO2",Juvenile,0.0068,1.0068,99.322,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, baseline, post, High CO2",Juvenile,0.2241,1.2512,79.924,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, first feeding, pre, Mid CO2",Juvenile,0.5421,1.7196,58.153,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, first feeding, pre, High CO2",Juvenile,0.1017,1.1071,90.33,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, first feeding, cue, Mid CO2",Juvenile,0.3928,1.4811,67.516,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, first feeding, cue, High CO2",Juvenile,0.0487,1.0499,95.247,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, first feeding, feed, Mid CO2",Juvenile,0.1187,1.126,88.807,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, first feeding, feed, High CO2",Juvenile,0.0428,1.0437,95.81,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, first feeding, post, Mid CO2",Juvenile,0.1749,1.1911,83.954,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, first feeding, post, High CO2",Juvenile,0.114,1.1208,89.226,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, DS response, pre, Mid CO2",Juvenile,0.1374,1.1473,87.162,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, DS response, pre, High CO2",Juvenile,0.0349,1.0355,96.57,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, DS response, cue, Mid CO2",Juvenile,0.2352,1.2652,79.041,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, DS response, cue, High CO2",Juvenile,0.0726,1.0753,92.997,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, DS response, feed, Mid CO2",Juvenile,0.1028,1.1083,90.231,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, DS response, feed, High CO2",Juvenile,0,1,100,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, DS response, post, Mid CO2",Juvenile,0.1301,1.1389,87.801,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, DS response, post, High CO2",Juvenile,0.0395,1.0403,96.127,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, post DS response, pre, Mid CO2",Juvenile,0.3058,1.3577,73.653,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, post DS response, pre, High CO2",Juvenile,0.0626,1.0646,93.932,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, post DS response, cue, Mid CO2",Juvenile,0.3693,1.4467,69.122,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator,"Posture, post DS response, cue, High CO2",Juvenile,0.0792,1.0824,92.386,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, post DS response, feed, Mid CO2",Juvenile,0.128,1.1366,87.985,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Posture, post DS response, feed, High CO2",Juvenile,0.0663,1.0685,93.585,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, post DS response, post, Mid CO2",Juvenile,0.0516,1.053,94.971,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,No,null,"Posture, post DS response, post, High CO2",Juvenile,0.0112,1.0113,98.886,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Feeding strikes, baseline, Mid CO2",Juvenile,0.101,1.1063,90.393,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Feeding strikes, baseline, High CO2",Juvenile,0.083,1.0865,92.035,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Feeding strikes, first feeding, Mid CO2",Juvenile,0.1841,1.2021,83.185,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Feeding strikes, first feeding, High CO2",Juvenile,0.0611,1.063,94.073,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator + food,"Feeding strikes, DS response, Mid CO2",Juvenile,0.0061,1.0061,99.392,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Predator + food,"Feeding strikes, DS response, High CO2",Juvenile,0.0356,1.0362,96.503,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Feeding strikes, post DS response, Mid CO2",Juvenile,0.1751,1.1914,83.937,
a87,Andrade et al,2018,2018,Behavioral responses of a coastal flatfish to predation-associated cues and elevated CO2,J Sea Res,1.729,1.729,Citharichthys stigmaeus,Subtrop,Yes,Food,"Feeding strikes, post DS response, High CO2",Juvenile,0.2374,1.2679,78.868,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Curvilinear velocity, mid CO2",Larvae,0.2364,1.2667,78.947,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Curvilinear velocity, high CO2",Larvae,0.4342,1.5438,64.777,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Response time, mid CO2",Larvae,0.6919,1.9975,50.062,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Response time, high CO2",Larvae,0.8425,2.3221,43.064,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Linearity of swimming path, mid CO2",Larvae,0.1624,1.1763,85.012,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Linearity of swimming path, high CO2",Larvae,0.4961,1.6423,60.89,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Wobble of swimming path, mid CO2",Larvae,0.1854,1.2037,83.079,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Wobble of swimming path, high CO2",Larvae,0.5312,1.701,58.787,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Latency time, mid CO2",Larvae,0.3328,1.3949,71.689,
a88,Jiahuan et al,2018,2018,"Ocean Acidification Impairs Foraging Behavior by Interfering With Olfactory Neural Signal Transduction in Black Sea Bream, Acanthopagrus schlegelii",Front Mar Sci,-,-,Acanthopagrus schlegelii,Subtrop,Yes,Food,"Latency time, high CO2",Larvae,1.5281,4.6093,21.695,
a89,Borges et al. ,2019,2019,Ocean warming and acidification may challenge the riverward migration of glass eels,Biol Lett,3.345,3.345,Anguilla anguilla,Temp,Yes,Habitat,"Proportion exhibiting migratory response, Geo test",Larvae,0.102,1.1074,90.303,
a89,Borges et al. ,2019,2019,Ocean warming and acidification may challenge the riverward migration of glass eels,Biol Lett,3.345,3.345,Anguilla anguilla,Temp,Yes,Habitat,"Number chose the kitasato with cue, Geo test",Larvae,0.3677,1.4444,69.232,
a89,Borges et al. ,2019,2019,Ocean warming and acidification may challenge the riverward migration of glass eels,Biol Lett,3.345,3.345,Anguilla anguilla,Temp,Yes,Habitat,"Proportion exhibiting migratory response, FW test",Larvae,0.0629,1.0649,93.904,
a89,Borges et al. ,2019,2019,Ocean warming and acidification may challenge the riverward migration of glass eels,Biol Lett,3.345,3.345,Anguilla anguilla,Temp,Yes,Habitat,"Number chose the kitasato with cue, FW test",Larvae,0.1823,1.2,83.335,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 0",Larvae,0.1021,1.1075,90.294,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 1",Larvae,0.1155,1.1224,89.092,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 2",Larvae,0.1729,1.1887,84.122,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 3",Larvae,0.1431,1.1538,86.667,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 4",Larvae,0.0801,1.0834,92.302,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 5",Larvae,0.2941,1.3419,74.52,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 6",Larvae,0.3781,1.4595,68.516,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 7",Larvae,0.333,1.3951,71.677,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, top figure panel, time 8",Larvae,0.2802,1.3234,75.563,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 0",Larvae,0.1021,1.1075,90.294,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 1",Larvae,0.0829,1.0864,92.044,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 2",Larvae,0.1095,1.1157,89.628,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 3",Larvae,0.1125,1.1191,89.36,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 4",Larvae,0.0653,1.0675,93.679,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 5",Larvae,0.1307,1.1396,87.748,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 6",Larvae,0.2262,1.2538,79.756,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 7",Larvae,0.203,1.2251,81.628,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, top figure panel, time 8",Larvae,0.2466,1.2797,78.145,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 0",Larvae,0.0535,1.055,94.791,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 1",Larvae,0.0487,1.0499,95.247,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 2",Larvae,0.026,1.0263,97.434,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 3",Larvae,0.0494,1.0506,95.18,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 4",Larvae,0.0382,1.0389,96.252,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 5",Larvae,0.0182,1.0184,98.196,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 6",Larvae,0.0494,1.0506,95.18,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 7",Larvae,0.0094,1.0094,99.064,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, mid CO2, bottom figure panel, time 8",Larvae,0.0181,1.0183,98.206,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 0",Larvae,0.0949,1.0995,90.946,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 1",Larvae,0.0273,1.0277,97.307,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 2",Larvae,0.0227,1.023,97.756,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 3",Larvae,0.0156,1.0157,98.452,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 4",Larvae,0.0043,1.0043,99.571,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 5",Larvae,0.0096,1.0096,99.045,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 6",Larvae,0.0441,1.0451,95.686,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 7",Larvae,0.027,1.0274,97.336,
a90,Hurst et al,2019,2019,"Elevated CO2 alters behavior, growth, and lipid composition of Pacific cod larvae",Mar Environ Res,3.159,3.159,Gadus macrocephalus,Boreal,Yes,Light,"Tank position, high CO2, bottom figure panel, time 8",Larvae,0.0136,1.0137,98.649,
a91,Laubenstein et al,2019,2019,A negative correlation between behavioural and physiological performance under ocean acidification and warming,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,No,null,Pre-cue strikes,Juvenile,0.1188,1.1261,88.799,
a91,Laubenstein et al,2019,2019,A negative correlation between behavioural and physiological performance under ocean acidification and warming,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,Yes,Food,Post-cue strikes,Juvenile,0.1547,1.1673,85.667,
a91,Laubenstein et al,2019,2019,A negative correlation between behavioural and physiological performance under ocean acidification and warming,Sci Rep,4.122,4.122,Acanthochromis polyacanthus,Trop,Yes,Food,Percent change in feeding strikes,Juvenile,0.5944,1.8119,55.189,
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