SWAT Literature Database for Peer-Reviewed Journal Articles

Title:Scenario-based impacts of land use and climate change on land and water degradation from the meso to regional scale 
Authors:Bossa, A. Y., B. Diekkuger and E. K. Agbossou 
Volume (Issue):6(10) 
Article ID: 
URL (non-DOI journals): 
Broad Application Category:hydrologic and pollutant 
Primary Application Category:climate change and land use change 
Secondary Application Category:pollutant cycling/loss and transport 
Watershed Description:49,256 km^2 Ouémé river, located primarily in Benin in western Africa 
Calibration Summary: 
Validation Summary: 
General Comments: 
Abstract:Scale-dependent parameter models were developed and nested to the Soil and Water Assessment Tool-SWAT to simulate climate and land use change impacts on water-sediment-nutrient yields in Benin at a regional scale (49,256 km²). Weighted contributions of relevant landscape attributes characterizing the spatial pattern of ongoing hydrological processes were used to constrain the model parameters to acceptable physical meanings. Climate change projections (describing a rainfall reduction of up to 25%) simulated throughout the Regional Model-REMO, very sensitive to a prescribed degradation of land cover, were considered. Land use change scenarios in which the population growth was translated into a specific demand for settlements and croplands (cropland increase of up to 40%) according to the development of the national framework, were also considered. The results were consistent with simulations performed at the meso-scale (586 km2) where local management operations were incorporated. Surface runoff, groundwater flow, sediment and organic N and P yields were affected by land use change (as major effects) of −8% to +50%, while water yield and evapotranspiration were dominantly affected by climate change of −31% to +2%. This tendency was more marked at the regional scale as response to higher scale-dependent rates of natural vegetations with higher conversions to croplands. 
Keywords:SWAT; scaling; regionalization; nutrient loss; climate change; land use change