Study Number,Lead Author,Year,Title,Journal,Longitude,Latitude,Location of Study (Description),Country,Scale of Study?,Number of ES evaluated,Services Evaluated,Biodiversity Measured?;Data source and method of collection; ES indicators;,Data Source,Methods of Data Collection,Description of the resolution of GIS data,Use of hydrographic river networks,Use of land use coverage data >= 30m or 1:50 000,ES Indicators,Interactions,Stakeholder involvement,Uncertainty,Scenarios Considered,Pre-Existing Models Used,Monteary Valuation Presence,Monetary Valuation Methods,Monetary Valuation Approaches
1,Felipe-Lucia,2015,Ecosystem services_biodiversity relationships depend on land use type in floodplain agroecosystems,Land Use Policy,-1.816728,41.288584,"River Piedra, Spain",Spain,F,8,R1;R2;R15;S1;P1;P2;C1;C2;,"Y;F;six plant diversity indexes (richness, abundance, and true diversity for both plant species and growth forms);","S,SR;F;F;F;S,SR;S,SR;F;F;",G;N;N;N;G;G;N;N;,"Land use coverage derived from 1:50 000 crop and land use digital map, with field validation to confirm land use coverage",N,Y,"carbon storage above and below ground based on Land use type, equation based on national database plant data; organic matter layer thickness in topsoil sampled in the field 3 times over two years; organic matter content in top soil;Riparian quality index, estimated in the field by seven river bank attributes; average yield for each land-use; yearly above ground dry biomass accumulation by land-use type; number of educative pannel per land-use type;Number of area used for social amenity per land-use type;",Y,N,QL,N,,N,,
2,Kozak,2015,Using Flow-Ecology Relationships to Evaluate Ecosystem Service Trade-Offs and Complementarities in the Nation�s Largest River Swamp,Environmental Management,-91.226511,29.580526,"Atchafalaya River Basin, Louisianna, USA",USA,W,3,P3;R15;P4;,N,S;S;S;,N;N;N;,,,,"number of lockage events (times the lock was operated); kg nitrogen removed; weight-per-effort (kg/gill net-hour), catch-per-effort (individuals/electrofishing-hour), biomass (kg/gill net summer by year), total commercial landing (kg);",Y,N,QL,N,,N,,
3,Vaughn,2015,Drought-induced changes in flow regimes lead to long-term losses in mussel-provided ecosystem services,Ecology and Evolution,-95.25995,34.350053,"Kiamichi River, Oklahoma, USA",USA,MR,3,R6;R15;R15;,N,"F,S;F,S;F,S;",N;N;N;,,,,"mussel mean soft tissue dry mass derived from the number of mussel beds and laboratory derived filtration rates, measure based on the ability of musels to filter water and clear cholorphyll-a; laboratory derived excretion rates of nitrogen and phosphorous by mussels combined with field derived quantities of mussels; Use of measured mussel biomass and stiochiometric data from the literature to estimate nitrogen, phosphorous and carbon stored in mussel soft tissue;",N,N,QL,N,,N,,
4,Esselman,2015,"Landscape Prediction and Mapping of Game Fish Biomass, an Ecosystem Service of Michigan Rivers",North American Journal of Fisheries Management,-85.602365,44.314844,Michigan State Rivers,USA,MW,1,P3;,N,"S,SR;","G,M*;","River line geometry taken from the 1:100,000-scale National Hydrography Dataset (USEPA and USGS 2005) with modifications to provide a more accurate coverage",Y,Y,"Modelled fish biomass for each fishery based on secondary field data and landscape predictors (soil permeability, land cover, stream position, bedrock and surficial geology, climate, modeled hydrology, modeled stream temperature and phosphorous concentrations from other publications;",N,N,QT,N,,N,,
5,Fanaian,2015,"An ecological economic assessment of flow regimes in a hydropower dominated river basin: The case of the lower Zambezi River, Mozambique",Science of the Total Environment,34.758632,-16.945646,Lower Zambezi Basin (in Mozambique),Mozambique,W,5,P8;P9;P3;C2;R4;,N,S;S;S;S;S;,N;N;N;N;N;,,,,"power generated/year, sale price/year, costs; hectares under cultivation, average yield /ha, production cost; catch rate, current market price; wildlife stock, hunting permit and tourism; area flooded, infrastructure, agrilcultural, housing asset damage;",Y,N,QL,P,,Y,"AMP, AC",Direct market
6,Geng,2015,Land Use/Land Cover Change Induced Impacts on Water Supply Service in the Upper Reach of Heihe River Basin,Sustainability,98.34,37.43,"Heihi River Basin, China",China,W,1,P7;,N,"S,SR;",M;,he land use data was interpreted by CAS according to the Landsat Thematic Mapper (TM),N,Y,modelled water yield from InVEST;,N ,N,QL,P,InVest;,N,,
7,Fezzi,2015,The environmental impact of climate change adaptation on land use and water quality,Nature Climate Change,-1.363438,51.648232,Great Brittan,England,MW,2,R5;P5;,N,"S,SR;S,SR;",G;G;,"Land use created based on agricultural census data, which is collected on a 2km grid square basis",N,Y,"modelled concentration of Nitrate, modelled concentration of phosphate, includes land use, climate related variables, slope and altitude derived from secondary data model IHDTM; farm gross margin (land use and livestock data from census, soil data, calculated travel time for market input, costs);",Y,N,QT,C,,Y,,
8,Fan,2014,Spatial and Temporal Analysis of Hydrological Provision Ecosystem Services for Watershed Conservation Planning of Water Resources,Water Resources Management,142.406905,44.192778,Upper Teshio Watershed,Japan,W,3,P8;P7;P7;,N,"S,SR;S,SR;S,SR;",M;M;M*;,"The DEM was acquired from the Japanese Geographic Survey Institute (GSI; 50 _ 50 m). The land-use map from 2006 and vector soil data were obtained from the National Land Information Office in the Ministry of Land, Infrastructure, Transport and Tourism (MLIT; 50 _ 50 m)",N,Y,"modelled hydropower electricity production based on water yield output from SWAT, included unit price from secondary data; modelled crop production based on water yield output from SWAT; modelled resident water use based on population data;",N,N,QT,N,SWAT;,Y,MV,Direct market
9,Trabucchi,2014,Mapping Ecological Processes and Ecosystem Services for Prioritizing Restoration Efforts in a Semi-arid Mediterranean River Basin,Environmental Management,-0.10546,41.069156,"Martin River Basin, Northeast Spain",Spain,W,6,P7;R7;R1;R9;R2;C2;,N,"S,SR;S;S;S,SR;S,SR;S;",N;N;N;N;N;G;,"1 km resolution surface runoff, 350 resolution water recharge raster, 1:50,000 forest maps,",N,Y,modeled water volume (mm/year per km2 cell) obtained directly from national dataset; modeled water recharge (mm/year per 350 m2 cell) obtained from water authority; metric tonnes of CO2 from allometric models from research report; plant density (%) based on RUSLE model; organic carbon content (%) obtained from European Soil Database; viewsheds from important locations;,Y,N,QT,N,SIA; RCN; AM;,N,,
10,Fu,2014,Value of ecosystem hydropower service and its impact on the payment for ecosystem services,Science of the Total Environment,103.184004,31.431688,"Zagunao River Basin, Southwest China",China,MW,2,P7;P8;,N,"F,S,SR;F,S,SR;",M;M;,,,,Modeled water volume (InVEST); Modelled hydropower (Invest);,Y,N,QL,N,Invest;,Y,MV,Direct market
11,La Notte,2015,An ecological-economic approach to the valuation of ecosystem services to support biodiversity policy. A case study for nitrogen retention by Mediterranean rivers and lakes,Ecological Indicators,21.573861,38.164094,"Mediterranean river basins, Europe",Europe,MW,1,R5;,N,S;,M;,,,,tonnes of nitrogen retained;,N,N,N,N,GREEN;,Y,RC,Direct market
12,Sturck,2014,Mapping ecosystem services: The supply and demand of flood regulation services in Europe,Ecological Indicators,12.218046,46.421952,Europe,Europe,MW,1,R4;,N,"S,SR;",M;,,,,"Flood regulation supply index (STREAM model-determines response of hydrograph), flood regulation demand (ratio of flood damage-using Damages Scanner Model-to upstream contributing area);",N,N,QT,P,STREAM; DSM,N,,
13,Marques,2013,The impact of climate change on water provision under a low flow regime: A case study of the ecosystems services in the Francoli river basin,Journal of Hazardous Materials,1.134111,41.392578,"Francoli River Basin, Northeast Spain",Spain,W,1,P7;,N,"S,SR;",M;,,,,"water yield (mm per watershed per year), water scarcity (mm per watershed per year);",N,N,QT,C,InVEST;,N,,
14,Liu,2013,Bringing ecosystem services into integrated water resources management,Journal of Environmental Management,149.027422,-35.281867,"Murray-Darling Basin, Australia",Australia,W,7,P1;P9;R1;R11;C5;C2;C4;,Y;S;wetland species (counts);,"SR;S;S,SR;SR;SR;S;S;",N;N;N;N;N;N;N;,,,,grazing area (%);agricultural water use (GL/year); carbon storage capacity (tonnes of carbon stored/ha); native vegetation (%); wetlands with cultural significance (ha); recreational opportunities (counts); residential properties near rivers (counts);,Y,Y,QT,N,MCDA;,N,,
15,Gutierrez,2013,"Which are, what is their status and what can we expect from ecosystem services provided by Spanish rivers and riparian areas?",Biodiversity Conservation,-3.749219,40.463667,Spain,Spain,MW,20,P3;P7;P2;P2;P8;C8;R10;R1;R5;R9;R2;R11;R12;C1;C1;C4;C7;C4;C2;C1;,"Y;S;Vertebrates of rivers and riparian forest (total number of species, endemisms and endangered species) (N_), Biodiversity of aquatic invertebrates (N_), Number LIFE-Nature projects for the protection of threatened species of rivers and riparian forest (N_, �); Medicinal plants of rivers and riparian (unitless);","S;S,SR;S,SR;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;",N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;,,,,"Number and total weight of catches of river fish (N_ and Kg), Salmon catch (N_, Kg and �), Trout catch (N_, Kg and �), Crayfish catch (N_, Kg and �), Value of river fish production (�),Number and type of aquaculture facilities (N_), Total aquaculture production (N_ and Kg), Value of aquaculture production (�),Total number and weight of fish caught in rivers come from aquaculture (N_ and Kg), Sturgeon and caviar production (Kg and �), Employment in aquaculture (Number of people); Total renewable water resources (mm), Runoff (mm), Provision of water for drinking (litters/person/day), Provision and origin of water for agriculture (Hm3), Water produced by desalination (Hm3), Total water consumption (Hm3), Water consumption by drinking (Hm3), Water consumption by irrigation (Hm3), Water consumption by industry (Hm3), Hydropower water use (Hm3), Water consumed in cooling of thermal and nuclear power (Hm3), Aquaculture water use (Hm3), Water exploitation index (%), Water consumption index (%),Value of water (�/m3), VAB and water consumption by irrigation (M3/ha crop and Million �), PIB and provision of water for drinking and agriculture (Hm3 and Million �); Area occupied by riparian forests (Has), Wood produced by riparian forests (M3), Firewood produced by riparian forests (Tonnes and m3), Handicrafts with fibers from riparian plant species (�); Number and location gravel pits (N_), Production of sand and gravel (Million tonnes and �), Aggregates consumption (Million tonnes), Employment generated by the aggregates sector (Number of people), Number exploitation inland saline (N_), Salt production (Thousand tonnes), Value of salt (Thousand �), Employment generated by inland saline (Number of people), Production of mineral waters and spring waters (Million litters), Value of mineral waters and spring waters (Thousand �); Total production of hydroelectricity (GWh), Annual net consumption of electricity / Annual hydroelectric production (%), Hydraulic potential of Spanish hydrological basins (MW), Hydroelectricity production of Spanish hydrological basins (GWh), installed power and production of small hydroelectric power (MW); Importance of natural medicines rated based on expert opinion; Annual precipitation (mm), Annual average temperature (_C), Evapotranspiration (mm), Evaporation from reservoirs (Hm3, Hm3/m2), Humidity Index (unitless), CO2 emissions from wastewater (Giga-grams), CH4 emissions from wastewater (Giga-grams), N2O emissions from wastewater (Giga-grams); Carbon sequestered by plantations of Populus (tonnes CO2/ha/yr), Annual increase in carbon sequestration in living biomass of riparian forest (Tonnes C/ha/yr and Giga-grams CO2/ha/year), Organic carbon stored in fluvisols (tonnes C/ha); Snow (Hm3), Number and area of glaciers (N_, Has), Ground-water recharge (m), Soil water (Litters/m2), Hydrological state index (unitless), Regulated water in reservoirs (Hm3), Water stored in reservoirs / total water generated in Spanish watersheds (%), Water losses in distribution channels (Hm3 /yr), Recycled water (Hm3), Number of effluent sewage (N_), Number and efficiency of the treatment plants (N_), Waste treatment (M3/person/day), Sludge produced in treatment plants (Tonnes of dry matter), Point source pollution and diffuse pollution (N_), Fertilizer consumed (Kg/ha), BOD5 (Mg/l), Phosphorus concentration in surface water (�g/l P-PO4), Nitrate concentration in surface water (Mg/l), Salinity in surface water (�S/cm), General Quality Index (0-100), Ecological status of Spanish rivers (EU Water Framework Directive) (unitless), Chlorides in groundwater (Mg/l), Nitrate concentration in groundwater (Mg/l), Public financial investment in water quality (Million �); risk of gully erosion (Tonnes/ha/yr), Sediments accumulate in reservoirs (Tonnes.yr), Specific degradation Index ( average annual of solid input x sediment density / surface catchment) (Tonnes/km2/yr); Fluvisols surface (has), sludge produced in treatment plants used in agriculture (Thousand tonnes dry matter); number of floods (N_), Number of dry periods (N_), Hydrological State Index in terms of the incidence of the drought (0-1), Deaths caused by natural disasters (N_), Economic losses from natural disasters (�), Conservation status of riverbanks (unitless), Urbanized land surface (has); Number of introduced vertebrates in rivers and riparian (N_), Coefficient of integrity zoogeographic for inland fish (N_), Number of introduced aquatic invertebrates (N_), Introduced riparian and aquatic plants (N_), Economic cost of invasive species and eradication (�); Number of references on �ecosystem services�, �Spain� and �water� in ISI web knowledge (N_), Scientific articles published in Limnetica (Journal of the Limnology Iberian Society) (N_), Number of Congress relating to water (N_), Number of courses relating to water (N_), PhD theses relating to water and aquatic ecosystems, Number of public and private organizations that develop research on water (N_), Projects about Research + Development on water and aquatic ecosystems (N_); Traditional hydraulic systems (unitless), Occupations linked to rivers and riparian (unitless), Rivers and riparian plants used in gastronomy (unitless), Rivers and riparian plants used in other productive activities and recreation (unitless); Average age of human population (unitless), Linguistic richness: words related to water use, proverbs sayings and riddles (N_), Folklore: festivals and dances related to water (unitless), Legal and social organizations (unitless); Rites and beliefs related to water (unitless), religious places related to rivers and riparian: Las Romerias (N_), proverbs of water and religious cult (unitless), catastrophic events and religious cult; Scenic rivers (N_ y km), Number of visitors to National Parks including rivers (N_), Length of river altered by dams (km), Length of riparian affected by change of use (km); River fishing preserves (N_ y km), Quality Spanish river water for fishing (unitless), Number river fishing licenses (N_), Number river beaches (N_), Hot mineral spring water and users (N_), water sports unitless); Environmental Education Programs on water and aquatic ecosystems (unitless);",N,N,QL,N,,N,,
16,Huang,2013,Changes in the ecosystem service values of typical river basins in arid regions of Northwest China,Ecohydrology,87,37,"Tarim, Manas, Shiyang and Hiehi river basins (all adjacent one to the other, in NorthWest China",China,W,8,R16;R10;P7;R2;R17;P1;P2;C2;,Y;S;NA;,S;S;S;S;S;S;S;S;,N;N;N;N;N;N;N;N;,,,,NA *see comment section;NA *see comment section;NA *see comment section;NA *see comment section;NA *see comment section;NA *see comment section;NA *see comment section;NA *see comment section;,N,N,QT,N,,Y,"MV, BFT",Direct market
17,Vollmer,2013,Rivers as municipal infrastructure: Demand for environmental services in informal settlements along an Indonesian river,Global Environmental Change,106.83131,-6.122574,"Ciliwun River, Jakarta",Indonesia,MR,6,R17;C2;P1;P7;R17;R17;,N,F*;F*;F*;F*;F*;F*;,N;N;N;N;N;N;,,,,Interview use of direct sanity use of the river (yes/no);Interview use of the river for recreation (yes/no);Interview use of the river for harvesting plants (yes/no);Interview use of groundwater (yes/no);Interview use of the river for solid waste disposal (yes/no);Interview use of the river for sewage disposal (yes/no);,Y,Y,QT,N,,N,,
18,Bangash,2013,Ecosystem services in Mediterranean river basin: Climate change impact on water provisioning and erosion control,Science of the total environment,1.994022,41.784931,"Mediterranean Llobregat river basin, Catalonia",Spain,W,2,P7;R9;,N,S;S;,M;M;,,,,modelled water provision (InVEST); modelled erosion control (InVEST);,N,N,QT,C,InVEST;,N,,
19,Doi,2013,"Effects of biodiversity, habitat structure, and water quality on recreational use of rivers",Ecosphere,138.248315,36.204916,109 rivers across Japan,Japan,WR,3,C2;S1;R5;,Y;F;field samples (fish species richness);,"S,SR;S,SR;",N;N;N;,,,,"number of visitor particpating in fishing, playing walking or sports (field observations); river habitat stucture (% alteration, % forest vs. grass vs. gravel vs. sand, # of recreational sites); water quality (BOD, SS);",Y,N,QT,N,,N,,
20,Acuna,2013,Does it make economic sense to restore rivers for their ecosystem services?,Journal of Applied Ecology,-6.267975,41.074524,Anarbe reservoir basin,Spain,MR,4,P3;C2;R5;R9;,N,"F,S;S;F,S;F,S;",N;N;M*;M*;,,,,"Market price for fish (fish biomass per surface are of fish age 3-4 years old x market price of fish); Market price for fishing permit; avoided treatment cost for pollutant of interest (updatke rate, annual loading of pollutant, cumulative pollutant loading, discharge-field measure); avoided cost (amount of particulate matter that can be retained in a river multipled by marginal cost of removal);",N,N,QT,P,,Y,MV,Direct market
21,Fu,2013,Mapping the flood mitigation services of ecosystems _ A case study in the Upper Yangtze River Basin,Ecological Engeneering,100,27,Upper Yentze River Basin,China,W,1,R4;,N,"S,SR;",M*;,,,,"Flow: single-event rainfall, storm days, the curve number (a coefficient taking a value between 0-100 modified based on land use, permiability, soil moisture before rain, and topography), Capacity: average storm preceipitation reduced by the ecosystem in one year (mm)/ annual storm precipitation generating flooding, Value: Totlal number of storms, flood damage (RMB Yuan);",N,N,QL,N,,Y,AC,Direct market
22,Deines,2013,"The potential trade-off between artisanal fisheries production and hydroelectricity generation on the Kafue River, Zambia",Freshwater Biology,27.449394,-15.761106,Kafue River,Zambia,MR,2,P8;P3;,N,S;S;,N;N;,,,,Monthly discharge (m3s-1) (before and after dam building); CPUE (mass per mtre of net per night);,Y,N,QT,N,,Y,"RC, MV",Direct market
23,Miara,2013,Riverine ecosystem services and the thermoelectric sector: strategic issues facing the Northeastern United States,Environmental Research Letters,-76.725222,41.565864,Northeastern US,USA,MR,1,P7;,N,S;,M;,,,,"River Water available for cooling over a regional domain (available discharge, available discharge when power plants are operational, available discharge considering temperature requirements for cooling), water availability analyzed at 345 power plants that require river water;",N,N,QT,M,FrAMES;TP2M;,N,,
24,Lorenz,2013,Modelling the effects of recreational boating on self-purification activity provided by bivalve mollusks in a lowland river,Freshwater Science,14.41583,52.691535,Spree River,Germany,R,2,R5;C2;,N,F;F;,N;N;,,,,"mussel filtration capacity, measured experimentally in-situ; Cameras to record boating activity, and an acoustic doppler velocimeter used during experimental boating to obtain information waves (this was used to estimate impact of boating on mussel filtration capacity);",Y,N,QT,N,,N,,
25,Honey-Roses,2013,"Examining the Demand for Ecosystem Services: The Value of Stream Restoration for Drinking Water Treatment Managers in the Llobregat River, Spain",Ecological Economics,1.994036,41.784929,Llobregat river,Spain,MR,1,R13;,N,"F,S;",M;,,,,"stream hydrology (segment inflow,temperature inflow, Segment outflow, accretion temperature), stream geometry (node latitude, node elevation, width of node, terms, Manning's N), meteorology (mean daily air temp, relative humidity, wind speed, solar radioation, ground temperature thermal gradient) and assessment of field shading conditions (Topographic shade, vegetation shade) to determine stream temperature at the intake for the drinking water plant;",N,N,QT,P,SNTEMP;,Y,RE,Direct market
26,Sanchez-Canales,2015,Sensitivity analysis of a sediment dynamics model applied in a Mediterranean river basin: Global change and management implications,Science of the Total Environment,1.994036,41.784929,Llobregat river,Spain,W,2,R9;R5;,N,"S,SR;S,SR;",M;M;,All the calculations are made at a pixel resolution of 200 _ 200 m,N,Y,Universal Soil Loss Equation (exported and retained sediment) in InVEST;Universal Soil Loss Equation (exported and retained sediment) in InVEST;,Y,N,QL,N,InVEST;SA;,N,,
27,Shi,2015,Land Use Zoning for Conserving Ecosystem Services under the Impact of Climate Change: A Case Study in the Middle Reaches of the Heihe River Basin,Advances in Meteorology,99,39,Heihe River basin,China,MR,7,P1;P7;P6;R10;R2;R15;S3;,"Y;SR, G,M;Shannon diversity index calculated as the share of land use type i in total area of the landscape;","S,SR;S,SR;S,SR;S,SR;S,SR;S,SR;S,SR;",G(M);G(M);G(M);M;G(M);G(M);G(M);,"Uses a land cover classification data set developed by the Chinese Academy of Sciences as the background data for spatially identifying the ecosystem services. The data set is derived from Landsat TM/ETMimages of bands 3, 4, and 5 with a spatial resolution of 30m_ 30m.",N,Y,"Cultivated land %; Water area %; Forestry area %; Air temperature, precipidation, sunshine hours; Loam proportion %, slope derived from DEM; Soil phosphorus content %; Net primary production (details on calculation NA);",N,N,QL,N,SIZES;,N,,
28,Nedkov,2012,"Flood regulating ecosystem services-Mapping supply and demand, in the Etropole municipality, Bulgaria",Ecological Indicators,24,42.83,Municipality of Etropole,Bulgaria,MW,1,R4;,N,"S,SR;",G(M);,"A DEM with 25 m resolution has been extracted from 1:25.000 topographic maps. The use of the widely accessible SRTM (Shut- tle Radar Topography Mission) 90 m DEM is also possible, but the accuracy of the results would be lower (Nedkov, 2007). The CORINE land cover (CLC) 2000 data was used as a main source for the capacity assessment and the mapping of flood regulation sup- ply and demand",Y,N,"Water storage capacity based on land-cover analyses asssessing soil, hydrology and climatic data;",N,N,QL,N,AGWA;KINEROS;SWAT;,N,,
29,Ligare,2012,NON-UNIFORM CHANGES TO WHITEWATER RECREATION IN CALIFORNIA'S SIERRA NEVADA FROM REGIONAL CLIMATE WARMING,River Research and Applications,-119.566013,37.72988,Sierra Nevada,USA,MR,1,C2;,N,"F,S,SR;",G;,"USGS 10_m digital elevation models (DEM), soil surveys from the Natural Resource Conserva-tion Service and land cover from the USGS",Y,N,Documented and field identified runable paddling routes;,N,N,QT,C,,N,,
30,Newton,2012,Cost_benefit analysis of ecological networks assessed through spatial analysis of ecosystem services,Journal of Applied Ecology,-2.157514,50.682458,"River Frome, Dorset",England,W,8,P5;P1;R1;P6;R4;C4;C2;C5;,"Y;S,SR,G;Species richness index and measure of habitat connectivity for species;","S,SR;S,SR;S,SR;S,SR;S,SR;F*;F*;F*;",G;G;G;G;G;G;N;N;,"UK Land Cover Map 2000 (LCM2000) (could be 25m or 1km, not specified in the data, so we assumed it was 1km)",N,Y,"Land cover type, census data from the government, and values of individual crops from another publication;Land cover type, census data from the government, and values of livestock from another publication; Carbon storage in vegetation and soil based on land cover type, derived from previously conducted study, value estimated based on governmental carbon prices; land cover and local yield data from a Forestry Commission; Index in relative change of flood risk by land use which uses land cover, soil types, rainfall, slope characteristics (developed by the Environmental Agency); Mapping-participants identify places of aesthetic value; Mapping- participants identify of up to 5 areas used for recreation and rate their importance; Mapping- participants identify of up to 5 areas that they value for their cultural heritage and rate their importance;",Y,Y,QT,P,,Y,"MV, RC",Direct market
31,Jujnovsky,2012,Assessment of Water Supply as an Ecosystem Service in a Rural-Urban Watershed in Southwestern Mexico City,Environmental Management,-99.173,19.15,Magdalena River Watershed,Mexico,W,1,P7;,N,"S,SR;",G(M);,"hydrologic network type from Avila-Akerberg (2002), but details only available in Spasnih",NA,NA,"Modeled with SWAT using: land cover, hydrologic network type, soil and vegetation type, precipitation, air temperature, solar radiation, wind speed, relative humidity;",N,N,QT,N,SWAT;,N,,
32,Notter,2012,Modelling water provision as an ecosystem service in a large East African river basin,Hydrology and Earth Systems Science,37.75,-4,Pangani Basin,"Tanzania, Kenya",W,1,P7;,N,"S,SR;",G(M);,Rivers networks from 1:250 000 topographic map from the University of Dar es Salaam,Y,Y,"Modeled with SWAT using: Daily rainfall & temperature, river discharge, land-cover;",N,Y,QT,N,SWAT;,N,,
33,Feng,2012,"Dynamics of Ecosystem Service Value Caused by Land use Changes in Manas River of Xinjiang, China",International Journal of Environmental Research,90.61507,26.515508,"Manas River, Xinjiang",China,W,8,R16;R10;P7;R2;R17;P1;P2;C2;,"Y;SR,G;land-use (as in Xie et al. 2003);","S,R;S,R;S,R;S,R;S,R;S,R;S,R;S,R;",G;G;G;G;G;G;G;G;,"1:100000 topographic map used, in addition to other 1:47 000 aerial photos to classify into six land use types (Note that we base our conclusion on the most coarse resolution data used)",N,Y,land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);land-use (as in Xie et al. 2003);,N,N,QL,N,,Y,MV,Direct market
34,Holland,2011,Spatial covariation between freshwater and terrestrial ecosystem services,Ecological Applications,-1.559571,52.333812,England and Wales,England,MW,5,R5;S1;R1;P5;C2;,"Y;S,G;Number of macroinvertebrate taxa (to family level) present within each 10 x 10 km grid cell & Terrestrial species of conservation concern from various national level Presence Absence data sets;","S;S;SR;S,SR;S;",G(M);G;G;G;G;,"1x1km resolution data to 10x10km resolution data, depending on the ecosystem service quantified",N,Y,"Taxa of invertebrates observed/taxa of invertebrates expected in an unstressed site, calculated using an Average Score per Taxon and the River Invertebrate Prediction and Classification System, average created for 10 x 10 km grid cells & River; Habitat Quality Assessment (frequency of channel features known to be of value to wildlife) & Habitat modification index (measure of extent of channel modification) (as in Raven et al. 1988) using GIS; soil and vegetation carbon based on land-cover at a 1 x 1 km grid resolution; Summed gross margin of major crops, timber and livestock, raw yields obtained from national database; Number of leisure visits from the National survey of leisure trips;",Y,N,QT,N,RIVPACS;,Y,GM,Direct market
35,Gathenya,2011,Agricultural conservation practices increase wetland ecosystem services in the Glaciated Interior Plains,Experimental Agriculture,34.920473,-0.179806,Nyando Basin,Kenya,W,2,R9;R7;,N,"S,SR;S,SR;",G(M);G(M);,DEM of 1:50000 to generate river network and land cover data for which the resolution was not specified,Y,Y,"Modeled with SWAT using: Land use, soil infiltration (Universal Soil Loss Equation); Modeled with SWAT using: precipitation, air temperature, air relative humidity, hours of sunshine, wind speed, stream flow from gages;",N,N,QL,PC,SWAT;,N,,
36,Gan,2011,Evaluation of the ecosystem values of aquatic wildlife reserves: a case of Chinese Sturgeon Natural Reserve in Yichang reaches of the Yangtze river,Journal of Applied Ichthyology,111.26,30.3,"Chinese Sturgeon Natural Reserve, in the middle of the Yangtze River",China,R,8,P3;P4;P9;C2;C1;C4;R5;S1;,N,S;S;S;S;S;S;S;S;,N;N;N;N;N;N;N;N;,,,,Fishery catch in annual tonnes; # of waterway passengers and annual transport capacity in tonnes; Mean water volume used for farmland irrigation and land cover; size of area and monetary value estimate from Costanza et al. (1997); Funds given to rescue by-catch & Support funds given to researchers; size of area & value from Costanza et al (1997); Tonnes of sediment transported; Size of area & monetary value from Costanza et al (1997);,N,N,QT,N,,Y,"MV, SV, EP, CV/WTP","Direct market, Revealed preference, Stated preference"
37,Sanchez-canales,2012,Sensitivity analysis of ecosystem service valuation in a Mediterranean watershed,Science of the total environment,1.994036,41.784929,"Llobregat basin, Catalonia",Spain,MW,1,P7;,N,"S,SR;",M;,,,,"Modeled with InVEST (Water yield: Average annual precipitation, annual reference evapotranspiration, correction factor for vegetation type, soil depth, plant available water content, land use and cover, root depth and elevation + Water scarcity: saturated hydraulic conductivity and consumptive water use);",N,N,QT,N,InVEST;,N,,
38,Pessacg,2015,Getting water right: A case study in water yield modelling based on precipitation data,Science of the Total Environment,-66.44699,-43.69057,"Chabut River basin, Patagonia",Argentina,MW,1,P7;,N,"S,SR;",M;,,,,"Modeled with InVEST (Root restricting layer depth, precipitation (comparison between gauges data and various satellite data as precipitation input to the model), plant available water content, reference evapotranspiration, land-use and cover, watersheds, subwatershed, root depth, plant evapotranspiration coefficient, seasonality factor (Z));",N,N,QT,N,InVEST;,N,,
39,Terrado,2015,"Landscape and local factors influence water purification in the Monteregian agroecosystem in Qu_bec, Canada",Regional Environmental Change,-73.170957,45.602229,"Mont_r_gie, Qu_bec",Canada,MR,1,R5;,N,"F,S,SR;",G;,"Used DEM and land use classification data from DMTI Spatial Inc., but the resolution of the data is not indicated",Y,NA,"Physicochemical (e.g. PhD, nitrate, conductivity, turbidity etc.) and geographic (e.g. proportion of watershet with agricultural land cover in 30m adjacent to stream, etc.) features;",N,N,QT,N,,N,,
40,Jujnovsky,2010,"Hydrologic ecosystem services: water quality and quantity in the Magdalena River, Mexico City",Hidrodiologica,-99.2,19.15,"Magdalena River, Mexico City",Mexico,W,2,R5;P7;,N,"F;S,SR;",N;M*;,,,,"pH, concudtivity, temperature, depth, dissolved solids, dissolved oxygen, ammonia, nitrates, total nitrogen, total phophorus, total organic carbon, total coliform, fecal coliform, streptococci, diatoms & diatomological indexes; topography, vegetation, precipitation, temperature, and geology using the Thornthwaite-matter method to estimate water balance-Data came from meteorological stations;",N,N,QL,N,,N,,
41,Crossman,2010,Reconfiguring an irrigation landscape to improve provision of ecosystem services,Ecological Economics,149.027422,-35.281867,"Torrumbarry Irrigation Area, Murray-Darling Basin, Australia",Australia,MR,5,R5;R1;P5;R7;C4;,N,"S;S,SR;S,SR;S;S;",G;G(M);N;N;N;,NA,,,"river salinity caused by irrigation, measured by the sum of changes in drainage following land conversion, changes in salinity and dollar benefit of salinity avoided; carbon sequestration capacity for native tree plantation coverage using 3-PG tree productivity simulations model; Profit at full equity for each agricultural land use (includes price, yield & costs); Net present value of increased flows for improving health of a predominant ecological community (as measured in previous publication); Willingness to pay for landscape aesthetics changes (as documented in previous local study);",Y,Y,QT,P,3-PG;,Y,MV,Direct market
42,Polizzi,2015,Is ecosystem restoration worth the effort? The rehabilitation of a Finnish river affects recreational ecosystem services,Ecosystem Services,29.483394,64.124967,River Pajakkojoki,Finland,MR,2,C2;C5;,N,"S,F*;S,F*;",N;N;,,,,"questionnaire distributed by mulitiple means assessing activities undertaken and expenditures related to this, in addition to the use of existing regional data sets on campfire places, nature tourism, recreational fishing, harbours, beaches, canoeing routes, ski trails, snowmobile tracks, hiking routes, green infrastructure; Questionnaire regarding visits to the local chamber music festival and other historical sites, sites were documented based on secondary data;",N,Y,QL,N,,Y,"CV/WTP, IE","Stated preference, Revealed preference"
43,Elsin,2010,Valuing Drinking Water Provision as an Ecosystem Service in the Neuse River Basin,Journal of Water Resources Planning and Management,-76.504018,35.131341,"Neuse River Basin, North Carolina",USA,W,1,R5;,N,S;,N;,,,,Turbidity;,N,N,QL,N,,Y,"BT, AC",Direct market
44,Hoeinghaus,2009,Effects of River Impoundment on Ecosystem Services of Large Tropical Rivers: Embodied Energy and Market Value of Artisanal Fisheries,Conservation Biology,-56.735955,-26.67822,"Prana River basin,",Brazil,MR,1,P3;,N,S;,N;,,,,"Fish yield & value, as well as, fishing effort from public reports;",N,N,QL,N,,Y,MV,Direct market
45,Martinez,2009,Effects of land use change on biodiversity and ecosystem services in tropical montane cloud forests of Mexico,Forest Ecology and Management,-96.06,19.34,La Antigua watershed,Mexico,W,7,R5;R1;P7;R9;R12;P1;C2;,Y;F;Sampled trees and shurbs in ten 10m x 10m plots per watershed and calculated Simpson's diversity index for each land use and Jaccard Similarity index to compare land use types and then used Shannon-Wieners Index to calculate structural diversity;,"F;S,SR,R;S,SR,R;S,SR,R;S,SR,R;S,SR,R;S,SR,R;",N;G;G;G;G;G;G;,"Land use change from 1973 to 1989 was calculated from satellite Landsat images (May 5th 1973 and October 26th 1989) from the Global Land Cover Facility (http://glcf.umiacs.umd.edu/ index.shtml). The bands were coupled with ERDAS (v. 8.7). In order to make both images compatible and with the same spatial resolution, the 1989 image was sampled with a resolution of 57 m",N,Y,"Followed APHA method (Collected field data on conductivity, total suspended solids, alkalinity, nitrates, choride, calcum, sodium, magnisium & potassium only a monthly basis for a year); Satellite land use & transfer valuation; Satellite land use & transfer valuation; Satellite land use & transfer valuation; Satellite land use & transfer valuation; Satellite land use & transfer valuation; Satellite land use & transfer valuation;",N,N,QL,N,,Y,"BT, MV",Direct market
46,Boithias,2016,Analysis of the uncertainty in the monetary valuation of ecosystem services - A case study at the river basin scale.,Science of the Total Environment,1.994036,41.784929,Llobregat River Basin,Spain,W,4,P7;R15;R9;S1;,N,"S,SR;S,SR;S,SR;S,SR;",M;M;M;M;,,,,"Modelled water provisionning using InVEST (Difference between rainfall and evapotranspiration in the basin, resulting in net remaining water supply); Modelled Waste Treatment using InVEST (Total nitrogen and phosphorus removed from water in the basin); Modelled erosion protection using InVEST (Amount of sediments retained based on soil erosion rates); Modelled provision of habitat for species using InVEST (Suitability of land use type to provide habitat for biodiversity and anthropogenic threats that can impair habitat quality);",N,N,QT,N,InVEST;,Y,MV,Direct market
47,Swallow,2009,"Tradeoffs, synergies and traps among ecosystem services in the Lake Victoria basin of East Africa",Environmental Science and Policy,35,0,Nyando and Yala River Basins,Kenya,MW,2,R9;P5;,N,"S,SR;S,SR,F*;",G(M);G;,"Topographic data were obtained from a digital elevation model generated from digitized 50m-resolution topographical maps provided by Survey of Kenya., Experts from the DRSRS overlaid a 100 pointgrid over each 5 km x 2.5 km aerial photograph and assigned each point a unique land use, then assumed that land use in the whole area was proportionate to land use in the 100 sample points.",N,Y,"Modeled with SWAT using the Uniserval Soil Loss Equation (using information on land use, topography, soils, climate); area under production, yield and prices via surveys & aerial photographs;",Y,Y,QL,N,SWAT;,Y,MV,Direct market
48,Butler,2009,"Evaluating an ecosystem service provided by Atlantic salmon, sea trout and other fish species in the River Spey, Scotland: The economic impact of recreational rod fisheries",Fisheries Research,-3.535254,57.350113,River Sprey,Scotland,W,2,S1;P3;,N,F*;F*;,N;N;,,,,Surveys with anglers of good fishing locations and derived fish presence; Surverys on fishing effort and catch;,Y,Y,QL,N,,Y,IE,Revealed preference
49,Little,2009,Revealing the impact of forest exotic plantations on water yield in large scale watersheds in South-Central Chile,Journal of Hydrology,-72.2,-35.45,Purapel en Nirivilo and Cauquenes en El Arrayan watersheds,Chile,W,2,P7;P6;,N,"S;F,SR;",N;G;,Landsat 30m resolution,N,Y,Daily Streamflow data from gauges and precipitation from weather stations;Forest cover change over time based on temporal Landsat imagery and field validataion;,Y,N,QT,N,,N,,
50,GuoLiang,2007,Comparison of changes of typical river segment ecosystem service value in LRGR,Chinese Science Bulletin,101.41,24.41,Yuanjian River & Lancang River,China,MR,10,P7;P1;P2;R9;R15;S1;R4;R5;R15;R16;,N,"S,R;S,R;S,R;S,R;S,R;S,R;S,R;S,R;S,R;S,R;",G;G;G;G;G;G;G;G;G;G;,NA,Y,NA,"River runoff and storage volume of reservoir;Fish product and aquatic vegetables assessed by market value; market value of food and raw materials (lumber, firewood, fiber, medicine, gene resources);Amount of soil covered by riparian plants;Deposited nitrogen and phosphorous in the riparian zone;Protection expenses of providing habitat;Riparian vegetation seing as how the reservoir on the river regulates flooding;Release of volume of Nitrogen and Phosphorous into river segment;rehabilitation expenses saved by flowing water removing sand and nutrient substances to maintain an unblocked channel;fixation of CO2 and release of O2 by riparian forest and grassland;",Y,N,N,N,,Y,"SE, PE, RE, MV",Direct market
51,Wang,2009,"Ecosystem services assessment of two watersheds of Lancang River in Yunnan, China with a decision tree approach",AMBIO: A journal of the human environment,101.058517,24.705642,"Fengqin River catchement & Ziaojie Richer catchment, Luozha river, Yunnan Province",China,MW,2,R9;S3;,"Y;F;Numer of species per hectare and height of vegetation (as a metric of structural diversity, which is viewed as a contributor to biodiversity in this paper);","F,R,SR;F,R,SR;",G;G;,"Vegetation and land-use maps have been produced in conjunc- tion with visual interpretation of satellite imagery (Landsat 7
TM, 13143, date: 2001-04-23, pixel size_30 m x 30 m).",N,Y,"Canopy coverage measured by crown projection and Leaf area index, and normalized difference vegetation index (categorization of vegetation cover) , and vegetation density (basal area and herb abundance), erosion intensity (rill and spash pedestal);Annual crop production from land use data and field data and annual biomass increment;",N,Y,QT,N,,N,,
52,Guo,2007,Hydroelectricy Production and Forest Conservation in Watersheds,Ecological Applications,110.514599,31.030298,Yangtze River Basin,China,W,3,P8;R9;R7;,N,"S;S,F;S,R;",N;N;N;,,,,"Annual hydroelectric production in kWh from two years for production, variation modelled for dry and wet seasons using the total amount of water flow per year, the temporal distribution of water flow and the water level difference in the dam;Modelled difference in soil erion between forestlands and non-forestlands and cost of cleaning sediment, includes data from an 'in situ' survey;Modelled cpacaity of river water flow regulation by varying tree, soil and slope land use complexes (takes into account canopy interception, litter absorption, storage in soil and underground and groundwater discharge as well as the intensity of rainfall);",Y,N,QT,N,,Y,MV,Direct market
53,Vermaat,2016,Assessing the societal benefits of river restoration using the ecosystem services approach,Hydrobiologia,11.487751,51.665304,Eight paired river reaches in different countries in Europe,Europe,MR,10,P5;P1;P6;P2;P7;R4;R15;R1;C2;C4;,N,S;S;S;S;S;S;S;S;S;S;,N;N;N;N;N;N;N;N;N;N;,,,,"Hay, grass and fodder (crops/year); Dairy and meat (production/year); Wood harvested for construction, paper or fuel (production/year); Reed crop (crops/year); Drinking water production after bank or deep infiltration (m3/year); Avoided in-reach and downstream flood damage-calculated as area flooded times the crops lost, the reduced forest growth and property damage; Phosphorous or nitrogen mass removed during flooding (k/ha/year); Conservative estimates of above ground accumulation in C/ha/year for wetlands and woodlands); Hunting, fishing, kayaking number of issued liscences or rentals; value of scenic beautiful, biodiversity, having a better water quality and existence by various wtp questionaires that were compiled;",N,Y,QT,N,,Y,"MV, RC, AD, CV/WTP, CE","Direct market, Stated preference"
54,Fan,2016,"Optimal conservation planning of multiple hydrological ecosystem services under land use and climate changes in Teshio river watershed, northernmost of Japan",Ecological Indicators,142.25,44.33,Teshio River watershed,Japan,W,3,P7;R15;R9;,N,"S,SR;S,SR;S,SR;",G(M);G(M);G(M);,The digital elevation model (DEM) was acquired from the Japanese Geographic Survey Institute (GSI; 50 _ 50 m). The land use maps (1976 and 2006) and soil data were obtained from MLIT (50 _ 50 m),Y,Y,"SWAT modeled water yield (net amount of surface and ground water that leaves the watershed and contributes to stream flow), authors mention that water supply is locally used for hydropower, agriculgural irrigation and resident daily usage; SWAT estimate of removal of fertilizer inorganic and organic N and P by vegetation and soil cover;SWAT estimated sediment retention (Different with vegetation and bare soil vs actual Soil and vegetation retention, which is modeled);",Y,N,QT,PC,SWAT;,N,,
55,Reobeling,2016,Estimating cultural benefits from surface water status improvements in freshwater wetland ecosystems,Science of the Total Environment,-8.480193,40.473259,C_rtima watershed,Portugal,W,3,R5;C2;C4;,N,S;S;S;,N;N;N;,,,,"physico-chemical parameters (DO, BOD, pH, NO3, P) and macro-invertebrates (Number of taxa, EPT, Average score per taxon, total number of individuals, and South Invertebrate portugese index; Willingness to pay for outings, boating, fishing and swimming, relationship curves estimated by Van Houtven et al. (2007) & number of issued recreational fishing permits, and number of guests at the local hotel as well as downloaded trail maps; Willingness to pay for water appearance, clarity, colour, odour, algae, diversity, wildlife and ecology, relationship curves estimated by Van Houtven et al. (2007);",Y,N,QT,N,,Y,"BT, CV/WTP",Stated preference
56,Carvalho-Santos,2016,Assessing the effects of land cover and future climate conditions on the provision of hydrological services in a medium-sized watershed of Portugal,Hydrological Processes,-8.433802,41.886827,River Vez Watershed,Portugal,W,4,R5;P7;R9;R4;,N,"S,SR,R;S,SR,R;S,SR,R;S,SR,R;",G(M);G(M);G(M);G(M);,"20m resolution grid derived from contour line map 1:25 000 Land-cover map 2006, 1:25 000. Classes were aggregated into seven main cover classes",Y,N,"SWAT modeled water quality (Nitrate concentration and Nitrogen export); SWAT modeled water quantity (Total annual water yield, also included measures of water timing); SWAT modeled erosion control (soil erosion % of the basin under soil erosion risk); SWAT modeled flood regulation (flow duration curve and soil water content);",Y,N,QT,PC,SWAT;,N,,
57,Bai,2016,Impacts of land management on ecosystem service delivery in the Baiyangdian river basin,Environmental Earth Sciences,116.047298,38.867793,Baiyangdian River basin,China,W,2,P7;R15;,N,"S,SR;S,SR;",M;M;,,,,"Water yield and scarcity modeled with InVEST (input data includes soil depth, precipitation, plant-available water content, average annual potential evapotranspiration and land-cover, and, water consumption); InVEST modeled water purification nitrogen retention model (accounts for water yield, land use, nitrogen loading and filtration rates and water quality standards);",N,N,QT,N,InVEST;,N,,
58,Guo,2000,An assessment of ecosystem services: Water flow regulation and hydroelectric power production,Ecological Applications,110.868324,31.351424,"Xingshan County, Hubei Province",China,W,2,R7;P8;,N,"R,F;S;",G;N;,"The spatial database of vegetation, soil, and topography for Xingshan County is organized at the scale of 1:50000. The vegetation map was developed through visual interpretation of Landsat TM image on 15 Sep- tember 1995 together with an extensive field survey in Xingshan County in 1997. Six vegetation types are used in this study (Although this is not mentioned directly in the text, looking at their map it is clear that they have used some sort of hydrographic network)",Y,Y,"rate of canopy interception of rain, rate or water absorbed by litter, ground water storage, slope; Mean annual kWh;",Y,N,QT,N,,Y,MV,Direct market
59,Ye,2004,"Ecological service assessment of human-dominated freshwater ecosystem with a case study in Yangzhou Prefecture, China",Journal of Environmental Sciences,119.412948,32.394213,"Yangzhou City, Jiangsu Province",China,MR,5,P7;R15;P3;S1;R4;,N,S;F;S;F;S;,N;N;N;N;N;,,,,"Water quantity in a local source over time (from other publications) and water consumption for industrial, agricultural and household uses in m3; measures of Diaphaneity (m), Total nitrogen (mg/L), Total phosphorous (mg/L), COD, Chlorophyll-a in one lake over time; Fish catch in tons over time (Three lakes in the study area); Zooplankton and Invertebrate sampling in one lake, compared to a reference lake; Occurence of floods over time and change in depth of rivers over the past 20 years (caused by silting);",N,N,QL,N,,N,,
60,Holmes,2004,"Contingent valuation, net marginal benefits, and the scale of riparian ecosystem restoration",Ecological Economics,-84.223813,35.620551,Little Tennessee River,USA,MR,4,R5;S1;C2;C4;,N,F*;F*;F*;F*;,N;N;N;N;,,,,"water clarity (estimated by expert ecologist judgment in discussion groups); fish habitat and wildlife habitat in river buffer zones (estimated by expert ecologist judgment in discussion groups); Allowable water uses (estimated by expert ecologist judgment in discussion groups, specific attributes not listed); Index of ecosystem naturalness (estimated by expert ecologist judgment in discussion groups);",Y,N,QL,P,,Y,"CE, CV/WTP",Stated preference
61,Fortier,2016,Potential for Hybrid Poplar Riparian Buffers to Provide Ecosystem Services in Three Watersheds with Contrasting Agricultural Land Use,Forests,-72.148042,45.266447,"Pike River, Eaton River and Magog river, all in Southern Qu_bec",Canada,MW,3,P6;R1;P13;,N,SR;S;S;,G;G;G;,"First, forest cover maps (1:20,000) from the study area were obtained from the Minist�re des For�ts, de la Faune et des Parcs (G_oboutique Qu_bec, QC, Canada) these were then used to detemrine the length of all streams (including intermitting ones)",Y,N,"Stem wood volume (m3)/above ground biomass that can be produced by poplars, based on previous study collecting information for 9 years;C, N and P stored in biomass, based on previous study results; Number of houses that could be heated by the energy derived from poplar woody biomass, based on a combination of local historical average energy requirements and woody biomass was adjusted for average moisture;",Y,N,N,P,,Y,MV,Direct market
62,Nelson,2009,"Modeling multiple ecosystem services, biodiversity conservation, commodity production, and tradeoffs at landscape scales",Frontiers in Ecology and the Environment,-122.939407,44.948978,"Willamette Basin, Oregon",USA,W,4,R5;R7;R2;R1;,"Y;S,SR,M;Species-area relationship to determine capacity of land use and cover to support 24 different vertebrates;","S,SR;S,SR;S,SR;S,SR;",M;M;M;M;,,,,"InVEST: Discharge of dissolved phosphorous into local watershed estimated using slope, soil depth and surface permeability; InVEST: Volume and timing of water flow from area to catchment outlet based on water retention characteristics of land use, areas that contribute less to water retention have higher storm peak retention (water flow); InVEST: USLE to predict annual rate of soil erosion, which is a function of land use, soil type, rainfall intensity, and topography; InVEST: carbon in above ground and belowground biomass, soil and harvested wood products using carbon accounting models, considred stored and harvested carbon;",Y,Y,QT,P,InVEST;,Y,MV,Direct market
63,He,2015,"Meta-analysis for the transfer of economic benefits of ecosystem services provided by wetlands within two watersheds in Quebec, Canada",Wetland and Ecology Management,-72.911476,46.006324,"Yamaska and B_cancour river basins, Quebec",Canada,MW,4,S1;R9;R4;P1;,N,"S,SR;S,SR;S,SR;S,SR;",G;G;G;G;,Scale of 1:750000,N,Y,"Value based on land use and cover and review of values found in other studies, presence of service estimated based on expert judgement; Value based on land use and cover and review of values found in other studies, presence of service estimated based on expert judgement; Value based on land use and cover and review of values found in other studies, presence of service estimated based on expert judgement; Value based on land use and cover and review of values found in other studies, presence of service estimated based on expert judgement;",N,Y,QT,N,,Y,"BT, CV/WTP, MV, RE, TC","Stated preference, Direct market, Revealed preference"
64,Lleva,2009,"Relationship between the riverine nitrate-nitrogen concentration and the land use in the Teshio River watershed, North Japan",Sustainability Science,142.25,44.33,Teshio River Basin,Japan,W,2,R5;R15;,N,"F;S,SR;",N;G;,"50m resolution land use, with additional seperate river network mapped",Y,Y,"Water temperature, pH, conductivity, NO3-N, NO2-N, NH4-N, PO4 (all in mg/L); Residual N (MgN) calculated as the difference between nitrogen input (manure, chemical fertilizer, nitrate from rain, irrigation, and nitrogen-fixation) and output (crop harvest, crop by products and denitrification) of farmland, using a mass balance model and secondary data;",N,N,QT,N,,N,,
65,Spooner,2008,"A trait-based approach to species� roles in stream ecosystems: climate change, community structure, and material cycling",Oecologia,-96.401441,34.913004,"Little River, Southern Oklahoma",USA,MR,1,R15;,N,F;,N;,,,,"Mussel bed excretion of Nitrogen, calculted by NH3, P, molar N:P excretion and biodeposition rate of mussels subject to different temperature treatment, results were extrapolated to mussel beds by measuring mussel densities in the field;",N,N,QT,C,,N,,
66,Vollmer,2015,Understanding the value of urban riparian corridors: Considerations in planning for cultural services along an Indonesian river,Landscape and Urban Planning,106.83131,-6.122574,"Ciliwung river, Jakarta, Indonesia",Indonesia,MR,3,C2;C4;C5;,N,F*;F*;F*;,N;N;N;,,,,"Observations, interviews and household surveys to determine if the service was a promenent ES for the community, including WTP; Observations, interviews and household surveys to determine if the service was a promenent ES for the community, including WTP; Observations, interviews and household surveys to determine if the service was a promenent ES for the community, including WTP;",N,Y,QL,P,Statistics;,Y,CE,Stated preference
67,Schnegg,2014,"Culture, Nature, and the Valuation of Ecosystem Services in Northern Namibia",Ecology & Society,20.142,17.54,"Mahahe, Okavanga Basin, Namibia",Namibia,MR/F,9,P2;P13;P1;P7;C4;C8;C1;C5;C7;,N,F*;F*;F*;F*;F*;F*;F*;F*;F*;,G;G;G;G;G;G;G;G;G;,,,,"Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can obtain building materials'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can find sources of energy'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can obtain food'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can obtain fresh water'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can experience beauty'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can find what you need to stay healthy or to become healthy when you are sick'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can learn something'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can go for physical exercise and training' or 'places where you can be heard it you have an announcement to make' or 'places where you feel at home and experience a sense of belonging' or 'places where you can meet people and have a good time with them'; Ethonographic particpant observations, semistructured interviews, and participatory mapping of landscape values asking about 'places where you can go to pray and express your spirituality and religion';",Y,Y,QL,N,,N,,
68,Rodriguez,2015,National ecosystems services priorities for planning carbon and water resource management in Colombia,Land Use Policy,-74.297333,4.570868,Colombia,Colombia,MW,5,P7;R7;R9;R1;R1;,N,"S,SR;S,SR;S,SR;S,SR;S,SR;",G;G;G;G;G;,data at a spatial resolution of 2 km,N,Y,"Map of water yield of Columbia (mean annual conditions) produced by IDEAM which was at a 2km resolution calculated superficial water quantity per unit catchement surface area as precipitaiton - real evapotranspiration; Rentention and hydrological regulation index (area below the mean flow linea and area below the daily flow duration curve; Use of national landslipe susceptibility map as a proxy, map analysed geological geomorphologic, edaphic variables and vegetation cover to identify areas that should be managed for hazard prevention in the face of erosion- the map establishes 5 degrees of suceptibility; capacity of land cover type to fix carbon above ground, estimates derived from allometric models of Above ground carbon storage, all estimates derived from previous work; Map of organic carbon distribution in columbian soils (incorporated geomorphology, climate, physical and chemical soil properties and soil taxonomic classes for each soil unit in the country);",Y,N,QT,N,,N,,
69,Castro,2016,Social Demand for Ecosystem Services and Implications for Watershed Management,Journal of the American Water Resources Association,-95.25995,34.350053,"Kiamichi River, Oklahoma",USA,W,8,P7;R7;R5;R18;S1;C2;C5;C5;,,F*;F*;F*;F*;F*;F*;F*;F*;,N;N;N;N;N;N;N;N;,,,,"Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;Invertiew participants throughout the watershed asked to rank the relative importance/presence of the ES currently, over the past 10 years and under multiple alternative water flow scenarios;",Y,Y,QL,P,,N,,
70,Silvano,2008,Contributions of ethnobiology to the conservation of tropical rivers and streams,Aquaric Conservation: Marine and freshwater Ecosystems,-59.96824,-3.162138,Macabuzinho river,Brazil,MR,5,P7;P7;R4;R13;R2;,N,"F*,F;F*,F;F*;F*;F*;",N;N;N;N;N;,,,,"Interviews with local farmers that live on the river or one of its tributaries to ask them about how they use and benefit from the water and forest on their property, some mentioned that they drink water from groundwater and others from the rivers,Field assessment of the ecological integrity of the river using the Stream Visual Assessment Protocol (SVAP) which visually looks at up to 15 elements and is used as a proxy for this ES (In this study these included: channel condition, hydrological alteration, riparian zone condition, bank statibility, water appearance, nutrient enrichment, barriers to fish movement, fish cover in the stream, pools, intertebrate habitat, canopy cover, presence of manure, riffle, embeddedness and presence of macroinverts);Interviews with local farmers that live on the river or one of its tributaries to ask them about how they use and benefit from the water and forest on their property, some mentioned that they saw a change in the water level of the river over time, Field assessment of the ecological integrity of the river using the Stream Visual Assessment Protocol (SVAP) which visually looks at up to 15 elements (In this study these included: channel condition, hydrological alteration, riparian zone condition, bank statibility, water appearance, nutrient enrichment, barriers to fish movement, fish cover in the stream, pools, intertebrate habitat, canopy cover, presence of manure, riffle, embeddedness and presence of macroinverts);Interviews with local farmers that live on the river or one of its tributaries to ask them about how they use and benefit from the water and forest on their property, some mentioned that that noticed a change in the flood line of the river;Interviews with local farmers that live on the river or one of its tributaries to ask them about how they use and benefit from the water and forest on their property, some mentioned that the forest was an important cooler of the environment;Interviews with local farmers that live on the river or one of its tributaries to ask them about how they use and benefit from the water and forest on their property, some mentioned that the forest played a role in the enrichement of soil organic matter;",Y,Y,QL,N,,N,,
71,Miller,2015,Estimating indigenous cultural values of freshwater: A choice expriment approach to Maori values in New Zealand,Ecological Economics,171.223347,-43.753679,Canterbury Region,New Zealand,W,5,P5;S1;R5;C2;C5;,N,S;S;S;S;F*;,N;N;N;N;N;,,,,"Number of job associated with agricultureal land use and survey of willingness to pay for alternative values under different scenarios;QT macroinvertebrate community index and survey of willingness to pay for alternative values under different scenarios; QT macroinvertebrate community index (used as a proxy for water quality due to invertebrate sensitivity to pollution and changes in surrouding environment) and survey ofwillingness to pay for alternative values under different scenarios;Proportion of popular sites in the region suitable for swimming (based on the suitability for recreation grade assessment published annually by the government) and survey ofwillingness to pay for alternative values under different scenarios; Cultural health index, an index developed for using Maori communitities' in-depth knowledge about how cultural values are assocaited with freshwater and environmental management, this index includes traditional associations, cultural stream health and a composite that assesses species availability, ongoing abilities to harves and access sites and perception and use of sites, willingness to pay for this form of service under different scenarios was also assessed;",Y,Y,QT,P,,Y,CV/WTP,Stated preference
72,Bohensky,2006,Future Ecosystem Services in a Soutern African River Basin: a Scenario Planning Approach to Uncertainty,Conservation Biology,27.253173,-30.107368,Gariep River Basin,South Africa,W,4,P1;P7;P13;P2;,"Y;F*;Group participatory identification of major ecosystem services in the basin, Biodiversity was considered to be one of the major factors important to other ES;",F*;F*;F*;F*;,N;N;N;N;,,,,Group participatory identification of major ecosystem services in the basin;Group participatory identification of major ecosystem services in the basin;Group participatory identification of major ecosystem services in the basin;Group participatory identification of major ecosystem services in the basin;,Y,Y,QL,P,,N,,
73,Lewan,2002,"Knowledge and recognition of ecosystem services amont the general public in a drainage basin in Scanio, Southern Sweden",Ecological Economics,13.042117,55.752894,Kavlinge River Drainage basin,Sweden,W,10,P7;C4;R1;R15;R2;C2;C2;C2;R12;R15;,"Y;F*;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this 'ES' (""Wild plants and animals"") in relation to the 10 other ES selected for assessment in this study;",F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;,N;N;N;N;N;N;N;N;N;N;,,,,"Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""rainfall"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Opportunities for enjoying silence"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Carbon dioxide uptake by growing trees/plants"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Wetlands' plant nutrient reduction"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Contribution of weathering to soil fertility"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Opportunities for hunting"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Opportunities for fishing"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Other opportunities for enjoying nature"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Predation by birds of vermin insects"") in relation to the 10 other ES selected for assessment in this study;Questionnaire answered by 58 randomly selected farmers in which they were asked to rank the importance of this ES (""Nitrogen uptake by legumious plants and alders"") in relation to the 10 other ES selected for assessment in this study;",N,Y,QL,N,,N,,
74,Loomis,2000,Measuring the total economic value of restoring ecosystem services in an impaired river basin: results from a contingent valuation survey,Ecological Economics,-98.283342,41.063985,South Platte River,USA,MR,5,R5;R9;S1;R17;C2;,N,F*;F*;F*;F*;F*;,N;N;N;N;N;,,,,Survey of willingness to pay a higher water bill to obtain a better water quality;Survey of willingness to pay a higher water bill to obtain improved control of erosion into the river;Survey of willingness to pay a higher water bill to provide more habitat to wildlife and fishes;Survey of willingness to pay a higher water bill in order for the river to do a better job at diluting wastewater;Survey of willingness to pay a higher water bill to obtain more areas to do recreational activities in;,Y,Y,QL,P,,Y,CV/WTP,Stated preference
75,Jorda-Capdevilla,2015,An ecosystem service approach to understand conflicts on river flows: local views on the Ter River (Catalonia),Sustainability Science,2.947485,42.054842,Ter River,Spain,MR,23,R15;R9;R7;P2;P7;P7;P1;P7;P7;P9;P6;P8;R4;P7;C2;C4;C2;C1;C4;C5;C2;C2;C2;,N,F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;,N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;,,,,"Supply of nutrients that preserve the coastal ecosystem (This ES was identified by interviewees as benefits people obtain from ecosystems); Supply of nutrients that can help preserve coastal ecosystems (This ES was identified by interviewees as benefits people obtain from ecosystems); Supply of a variable flow regime, maintenance of aquifer levels, maintenance of the walk wedge away which all contribute to the preservation of wetlands (This ES was identified by interviewees as benefits people obtain from ecosystems); Supply of sand and gravel that allow for extraction (This ES was identified by interviewees as a benefit people obtain from ecosystems); Supply of a minimum water flow to generate artificial snow production (This ES was identified by interviewees as a benefit people obtain from ecosystems); the supply and storage of clearn water and the maintenance of salt wedge away (This ES was identified by interviewees as a benefit people obtain from ecosystems); provisioning of otters for their skin and meat (This ES was identified by interviewees as a benefit people obtain from ecosystems); supply of water to maintain a grazing location for livestock (This ES was identified by interviewees as a benefit people obtain from ecosystems); supply of water for industry (This ES was identified by interviewees as a benefit people obtain from ecosystems); Supply of water for intensive farming (This ES was identified by interviewees as a benefit people obtain from ecosystems); the extraction of timber to provide wicker, alder, poplar timber for basketry, turnery and shoddy wood (This ES was identified by interviewees as a benefit people obtain from ecosystems); Supply of water flow sufficient to generate hydropower (This ES was identified by interviewees as a benefit people obtain from ecosystems); security against floods through the transport of flood flows, the maintenance of a river channel clean of vegetation, the maintenance of a natural riparian forest in the floodplain (This ES was identified by interviewees as a benefit people obtain from ecosystems); Water supply and flow of clean water to be able to wash clothes with (This ES was identified by interviewees as a benefit people obtain from ecosystems); Angling, the production of healthy and edible species for recreation; Appreciation of the natural environment (contribution to the beauty and support of biodiversity) (This ES was identified by interviewees as a benefit people obtain from ecosystems); water flow with right conditions for boating (This ES was identified by interviewees as a benefit people obtain from ecosystems); Education and research (This ES was identified by interviewees as a benefit people obtain from ecosystems); relaxing to the sound of a flowing stream and having inspiration (This ES was identified by interviewees as a benefit people obtain from ecosystems); river-related cultural heritage (This ES was identified by interviewees as a benefit people obtain from ecosystems); swimming (This ES was identified by interviewees as a benefit people obtain from ecosystems); tourism (This ES was identified by interviewees as a benefit people obtain from ecosystems); walking, jogging and cycling (This ES was identified by interviewees as a benefit people obtain from ecosystems);",Y,Y,QL,N,,N,,
76,Lu,2015,Trade-offs between midstream agricultural production and downstream ecological sustainability in the Heihe River basin in the past half century,Agricultural Water Management,99,39,Heihe River Basin,China,MW,2,P5;P7;,N,S;R;,N;G;,"Landsat, air photo resolution not given",N,Y,"cultivated land, cereal production;area of oases;",Y,N,N,N,,N,,
77,Hupp,2015,"Patterns of floodplain sediment deposition along the regulated lower Roanoke River, North Carolina: Annual, decadal, centennial scales",Geomorphology,-77.159547,35.979469,Lower Roanoke Basin,USA,F,1,R9;,N,F;,N;,,,,"artificial markers (clay pads), tree-ring (dendrogeomorphic) techniques, and pollen analyses;",N,N,QT,N,,N,,
78,Adams,2014,Navigating trade-offs in land-use planning: integrating human well-being into objective setting,Ecology & Society,130.686872,-13.752026,"Daly Catchment, Northern Territoru",Australia,W,19,S1;S1;C4;C5;P2;C2;P5;P2;P1;P6;C4;C5;C5;C1;C5;C5;C2;C2;P1;,N,F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;,N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;,,,,"focus group (5-20 people) prompted with questions, What contributes most to your happiness?The river provides habitat for iconic species (like barramundi, black bream, long-neck turtles, sawfish);focus group (5-20 people) prompted with questions, What contributes most to your happiness? The catchment provides habitat for a variety of plants and animals; focus group (5-20 people) prompted with questions, What contributes most to your happiness? A place where the river flows naturally and there are no dams;focus group (5-20 people) prompted with questions, What contributes most to your happiness? A place for natural heritage (e.g., important National Parks and unique environments); focus group (5-20 people) prompted with questions, What contributes most to your happiness?A place for development and intensified production;focus group (5-20 people) prompted with questions, What contributes most to your happiness? The tourism industry in the catchment provides jobs and income;focus group (5-20 people) prompted with questions, What contributes most to your happiness? The agricultural industry in the catchment provides jobs and income;focus group (5-20 people) prompted with questions, What contributes most to your happiness? The mining industry in the catchment provides jobs and income;focus group (5-20 people) prompted with questions, What contributes most to your happiness? The cattle industry in the catchment provides jobs and income;focus group (5-20 people) prompted with questions, What contributes most to your happiness? The forestry industry in the catchment provides jobs and income;focus group (5-20 people) prompted with questions, What contributes most to your happiness? A place that is relatively free from congestion and major development;focus group (5-20 people) prompted with questions, What contributes most to your happiness? A place that supports families and communities;focus group (5-20 people) prompted with questions, What contributes most to your happiness? A place to preserve traditional (e.g. Indigenous) cultural values; focus group (5-20 people) prompted with questions, What contributes most to your happiness? A place for research, teaching, and learning; focus group (5-20 people) prompted with questions, What contributes most to your happiness? It is important to keep the area in good condition for future generations; focus group (5-20 people) prompted with questions, What contributes most to your happiness? Even if I could never visit ANY part of the Daly, I would still like to know �it is there�;focus group (5-20 people) prompted with questions, What contributes most to your happiness? Fishing and hunting for fun;focus group (5-20 people) prompted with questions, What contributes most to your happiness? Swimming, camping, boating, being in country;focus group (5-20 people) prompted with questions, What contributes most to your happiness? Fishing and hunting for fresh food;",N,Y,QT,N,,N,,
79,Pataki,2013,A Methodology for Adaptable and Robust Ecosystem Services Assessment,Environmental Science and Policy,18.86881,46.224947,Gemenec Floodplain,Hungary,F,10,S1;S1;R4;R5;P2;P7;P5;C5;C2;C2;,N,F*;F*;F*;F*;F*;F*;F*;F*;F*;F*;,N;N;N;N;N;N;N;N;N;N;,,,,consultation with local experts and stakeholders (Habitat for characteristic flora and fauna);consultation with local experts and stakeholders (Maintenance of genetic diversity);consultation with local experts and stakeholders;consultation with local experts and stakeholders;consultation with local experts and stakeholders;consultation with local experts and stakeholders;consultation with local experts and stakeholders;consultation with local experts and stakeholders;consultation with local experts and stakeholders (Ecotourism);consultation with local experts and stakeholders (recreation);,N,Y,N,C,,N,,
80,Norman,2013,"Framing Scenarios of Binational Water Policy with a Tool to Visualize, Quantify and Valuate Changes in Ecosystem Services",Water,-110.798312,31.524753,"Santa Cruz Watershed, Arizona",USA,W,2,P7;S1;,N,"S,R,F*;S;",M;G;,Not reported,NA,NA,"SWAT-discharge/recharge, replacement costs for water treatment-benefits transfer, williness to pay survey;terrestrial vertebrate species richness quantified using maps and model;",N,Y,N,P,SWAT;,Y,"BT, HP, CV/WTP","Revealed preference, Stated preference"
81,Kubiszewski,2013,Hydropower development in the lower Mekong basin: alternative approaches to deal with uncertainty,Regional Environmental Change,102.86147,17.937637,Lower Mekong basin,"Lao PDR, Thailand, Cambodia, Viet Nam",W,20,P8;P9;P3;P7;R4;R17;R4;P1;P2;S1;C1;C4;R1;R16;S1;P5;R4;R5;R9;P4;,Y;S;monetary valuation;,S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;S;,N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;N;,,,,"replacement cost of hydropower based on other study;replacement cost of irrigated agriculture based on other study; replacement cost of reservoir fisheries, aquaculture and capture fisheries based on other study;replacement cost of wetland area based on other study;replacement cost of wetland area based on other study; replacement cost of wetland area based on other study;replacement cost of wetland area based on other study;replacement cost of wetland area based on other study;replacement cost of wetland area based on other study;replacement cost of wetland area based on other study; replacement cost of wetland area based on other study;replacement cost of wetland area based on other study;replacement cost of wetland area based on other study;replacement cost of wetland area based on other study;replacement cost of forest area based on other study; replacement cost, not clearly identified;replacement cost of flood damage mitigation based on other study; replacement cost of mitigation of salinity for water quality based on other study; replacement cost of losses in bank erosion based on other study;replacement cost of navigation based on other study;",Y,N ,QL,C,,Y,"MV, RC",
82,Grossman,2012,Economic value of the nutrient retention function of restored floodplain wetlands in the Elbe River Basin,Ecological Economics,11.64033,52.115859,Elbe River catchment,Germany,W,1,R15;,N,S;,"M,G;",Model moneris. No mention of resolution,NA,NA,"replacement cost of N retention with MONERIS, replacement cost of P retention with MONERIS;",N,N,QL,N,MONERIS;,Y,RC,Direct market
83,Bouletreau,2012,Temperature dependence of denitrification in phototrophic river biofilms,Science of the Total Environment,1.774444444,46.04333333,"Douctouyre stream, Vira",France,R,1,R15;,N,F;,N;,,,,rate of NO2 production (DEA0);,N,N,N,N,,N,,
84,Tuvendal,2011,Ecosystem Services Linking Social and Ecological Systems: River Brownification and the Response of Downstream Stakeholders,Ecology and Society,14.143062,56.032259,"River Helge, Kristianstads",Sweden,R,10,C2;C2;C2;C2;C4;P5;P9;C2;C2;R5;,N,"F*,S;F*;F*,S;F*,S;F*,S;F*;F*,S;F*,S;F*,S;F*,S;",N;N;N;N;N;N;N;N;N;N;,,,,"Bathing in freshwater' interview with head of Kristianstad tourist office, municipality website with data on location and status of water quality for outdoor bathing facilities run by the municipality; 'Bathing in the sea'Interviews with owner of largest shorefront Hotel, head of Kristianstad tourist office, managers Biosphere Office; 'Recreational fishing' Interviews with chair of regional recreational fishing association, two reports from the Biosphere Office on status of freshwater fish; 'Bird watching'Interview with manager from Biosphere Office, two reports from the Biosphere Office on bird populations; 'Attractiveness of shoreline', Interview with owner of largest shorefront Hotel, head of Kristianstad tourist office, municipality data on level of tourism in the region; 'Grazing and haymaking on the meadows' interview with two farmers; 'Irrigation for crops' Interviews with former chair of the largest irrigation system in the area (and Sweden), maps on irrigation systems; 'ecotourism' Interviews with manager from Biosphere Office, head of Kristianstad tourist office, owner of largest shorefront Hotel, web search; ""eel fishing"" map of placement of fishing gear, interviews with two eel fishers; ""drinking water"" Interview with municipality representative responsible for water, municipality website on water;",N,Y,N,C,,N,,
85,Koundouri,2016,Development of an integrated methodology for the sustainable environmental and socio-economic management of river ecosystems,Science of the Total Environment,-0.336887,52.144935,Anglian River,England,W,4,P7;R5;R9;S1;,N,S;S;S;S;,N;N;N;N;,,,,monetary valuation of provisioning services based on a literature review; monetary valuation of water treatement based on a literature review; monetary valuation of erosion protection based on a literature review; monetary valuation of habitat for species based on a literature review;,N,N,N,N,,Y,"BT, MV",Direct market
86,Baskaran,2009,Estimating the value of agricultural ecosystem services: a case study of New Zealand pastoral farming,Australian Journal of Environmental Management,173.377437,-41.798605,New Zealand,New Zealand,MW,4,R16;P9;R5;C4;,N,F*;F*;F*;F*;,N;N;N;N;,,,,"wtp survey for methane gas emissions from pastoral
farming; wtp survey for water usage for irriation of pastoral farms; wtp survey for nitrate leaching to water from pastoral farming; wtp for scenic view for pastoral farms;",Y,N,QT,P,,Y,CV/WTP,Stated preference
87,Broadbent,2015,Valuing preservation and restoration alternatives for ecosystem services in the southwestern USA,Ecohydrology,-110.39224,32.316817,"Sanpedro Riparian National Conservancy area, Middle Rio Grande",USA,MR,3,P7;S1;C2;,N,F*;F*;F*;,N;N;N;,,,,"WTP survey for average water flow per year; WTP survey for compsation of riparian vegetation by condition class and major vegetative species; WTP for breeding bird by nest heght and water dependency, WTP for average number of migratory birds;",Y,Y,QT,P,,Y,CV/WTP,Stated preference
88,Felipe-Lucia,2014,Interactions Among Ecosystem Services Across Land Uses in a Floodplain Agroecosystem,Ecology and Society,-1.699825,40.972528,Piedra river,Spain,MR/F,12,R10;R16;R2;R15;S1;P2;P1;C2;C2;C2;C1;C1;,N,"F;S;F;F;F;S;S;S;S;F;F;F,S;",N;G;N;N;N;G;G;G;G;G;G;G;,"Land use data compiled by the ministry of environment in Spain (resolution not specified), and hydrographic network data",Y,NA,"Mean of daily temeprature range by sampled land use type; Annual CO2 sequestration, includes above and below ground biomass of different present plant species; depth of organic matter on topsoil; total nitrogen in soil samples;Riparian Quality Index developed by Gonzalez del Tanago et al, 2006; Annual growth rate per plant species; Yield values of crops growing within the area (kilocalories per hectare); Available fishing stretches on river for reacreational use obtained from local fishing regulatory policy; Tracks of post-signed and user designed paths obtained from local tourist office website and wikilocs; Number of areas for social amenity per land use and municipatlity counted in the field, summed to the average number of rest areas per hectare for each land use; The number of notice boards with information about the ecosystem of the study area, counted on the ground and averaged to each land use type; Number of local associations related to the use of nature counted;",Y,N,QT,P,,N,,
89,Large,2015,"Using google eartch, a virtual-globe imaging platform, for ecosystem services-based river assessment",River Research Applications,136.651452,71.528221,"Yana River, Russia",Russia,WR,7,P3;P5;P6;P7;R4;R1;R5;,"Y;G;sinuosity, sceondary channel, no. of tributaries, active channel complexity, valley side connectivity, river/river corridor ratio, riparian woodland, floodplain habitat masaic, paleochannels, wetlands, floodplain forest, floodplain lakes, naturelalness;",R;R;R;R;R;R;R;,G;G;G;G;G;G;G;,The minimum reach length was set at 500_m,N,Y,"sinuosity, secondary channel, no. of tribuary, active channel complexity, riparian woodland, floodplain forest, instrability/naturalness; agriculture, floodplain lake, naturalness; woodland plantation; no. of tributaries, wetlands, floodplain lakes, naturalness; sinuosity, seconday channels, active channel complexity, slope, river/river corridor ratio, floodplain forest, woodland plantation, naturalness; paleochannels, wetlands, floodplain forest, floodplain lakes, naturalness; slope, river'riverine channel ratio, paleochannel, wetlands, floodplain forest, floodplain lakes, naturalness;",N,N,QL,N,,N,,