CMADS and CFSR Data-Driven SWAT Modeling for Impacts of Climate and Land-Use Change on Runoff

• Published in: Water (Basel) Vol. 15; no. 18; p. 3240
• Main Authors: Du, Bailin, Wu, Lei, Ruan, Bingnan, Xu, Liujia, Liu, Shuai
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.09.2023
• Subjects: agricultural land; Aquatic resources; Arid regions; China; climate; Climate change; data collection; Datasets; forest land; Geospatial data; Global temperature changes; Hydrology; Land use; land use change; Management; Precipitation; Precipitation (Meteorology); Runoff; Software; Soil and Water Assessment Tool model; Soil erosion; temperature; Water; Water conservation; Watersheds; China; Loess Plateau
• ISSN: 2073-4441; 2073-4441
• DOI: 10.3390/w15183240

Climate and land-use change significantly impact hydrological processes and water resources management. However, studies of runoff simulation accuracy and attribution analysis in large-scale basins based on multi-source data and different scenario projections are limited. This study employed the Soil and Water Assessment Tool (SWAT) model in conjunction with spatial interpolation techniques to evaluate the accuracy of Climate Forecast System Reanalysis (CFSR), China Meteorological Assimilation Driven Dataset (CMADS), and observation (OBS) in runoff simulations, and configured various scenarios using the Patch-generating Land-use Simulation (PLUS) model to analyze effects of climate and land-use changes on runoff in the Jing River Basin from 1999 to 2018. Results demonstrated the superior performance of the CMADS+SWAT model compared to than CFSR+SWAT model, as the latter underestimated peak runoff. Changes in precipitation had a stronger impact on runoff than temperature, with increased flow from farmland and strong interception effects from forestland. Integrated climate and land-use changes led to an average annual runoff reduction of 1.24 m3/s (I2), primarily attributed to climate change (1.12 m3/s, I3), with a small contribution from land-use change (0.12 m3/s, I4). CMADS exhibited robust applicability under diverse scenarios, effectively enhancing runoff simulation accuracy. The findings provide invaluable guidance for water resources management in semi-arid regions.