Influence of ecohydrologic feedbacks from simulated crop growth on integrated regional hydrologic simulations under climate scenarios

Hydrology and Earth System Sciences

Volumn 16, Issue 6, 2012, Pages 1577-1593

  Van Walsum, P E V ^a   Supit, I ^a  

^a WAGENINGEN UNIVERSITY   (Netherlands)

Author keywords

[No Author keywords available]

Indexed keywords

ACTUAL EVAPOTRANSPIRATION; ARABLE LAND; CAPILLARY RISE; CLIMATE SCENARIOS; CO2 CONCENTRATION; CROP COEFFICIENT; CROP DEVELOPMENT; CROP GROWTH; CROP SIMULATION MODEL; CROP SIMULATIONS; CROP YIELD; GROWING SEASON; HIGHER TEMPERATURES; HYDROLOGIC MODELLING; HYDROLOGIC SIMULATIONS; LEAF AREA INDEX; MODFLOW; PARAMETERIZATIONS; POTENTIAL TRANSPIRATION; RADIATION FRACTIONS; REGIONAL GROUNDWATER; ROOT ZONE; SOIL MOISTURE MODEL; STATIC AND DYNAMIC; STATIC MODEL; STORAGE CAPACITY; SUMMER HEAT; TWO-WAY COUPLING; VEGETATION PARAMETERS; WATER RETENTION CAPACITY;

CARBON DIOXIDE; CLIMATE CHANGE; CLIMATE MODELS; CROPS; DYNAMIC MODELS; GROUNDWATER; PARAMETERIZATION; RAIN; SOIL MOISTURE; TRANSPIRATION; WATER SUPPLY;

COMPUTER SIMULATION;

CARBON DIOXIDE; CLIMATE CHANGE; CLIMATE CONDITIONS; CLIMATE EFFECT; CROP PLANT; CROP YIELD; ECOHYDROLOGY; EVAPOTRANSPIRATION; FEEDBACK MECHANISM; FLOW MODELING; GRASS; GROUNDWATER FLOW; GROWING SEASON; GROWTH MODELING; HYDROLOGICAL MODELING; HYDROLOGICAL RESPONSE; INTERCEPTION; LEAF AREA INDEX; PARAMETERIZATION; POTATO; RECHARGE; RHIZOSPHERE; SOIL MOISTURE; SOIL WATER POTENTIAL; TEMPERATURE EFFECT; TRANSPIRATION; YIELD RESPONSE;

SOLANUM TUBEROSUM;

EID: 84861800952     PISSN: 10275606     EISSN: 16077938     Source Type: Journal    
DOI: 10.5194/hess-16-1577-2012     Document Type: Article

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