Abstract
Weather data are the key forces that drive hydrological processes so that their accuracy in watershed modeling is fundamentally important. For large-scale watershed modeling, weather data are either generated by using interpolation methods or derived from assimilated datasets. In the present study, we compared model performances of the Soil and Water Assessment Tool (SWAT), as driven by interpolation weather data, and NASA North American Land Data Assimilation System Phase Two (NLDAS2) weather dataset in the Upper Mississippi River Basin (UMRB). The SWAT model fed with different weather datasets were used to simulate monthly stream flow at 11 United States Geological Survey (USGS) monitoring stations in the UMRB. Model performances were evaluated based on three metrics: coefficient of determination (R2), Nash–Sutcliffe coefficient (NS), and percent bias (Pbias). The results show that, after calibration, the SWAT model compared well at all monitoring stations for monthly stream flow using different weather datasets indicating that the SWAT model can adequately produce long-term water yield in UMRB. The results also show that using NLDAS2 weather dataset can improve SWAT prediction of monthly stream flow with less prediction uncertainty in the UMRB. We concluded that NLDAS2 dataset could be used by the SWAT model for large-scale watersheds like UMRB as a surrogate of the interpolation weather data. Further analyses results show that NLDAS2 daily solar radiation data was about 2.5 MJ m−2 higher than the interpolation data. As such, the SWAT model driven by NLDAS2 dataset tended to underestimate stream flow in the UMRB due to the overestimation in evapotranspiration in uncalibrated conditions. Thus, the implication of overestimated solar radiation by NLDAS2 dataset should be considered before using NLDAS2 dataset to drive the hydrological model.
Highlights
Water resources are planned and regulated on a river basin scale so that the future design and evaluation of management practices depend on the total hydrologic and biogeochemical performance of the basin instead of singular hydrologic units [1,2,3]
Assessment Tool (SWAT) is one of these watershed models designed for simulating long-term water quantity and quality as impacted by land use and climate changes and best management practices at large-scale watersheds [6]
It is a semiphysical and semidistributed model accounting for major hydrological and biogeochemical processes significant at large spatial scale and medium to large temporal scale [8,9,10]. It divides a watershed into sub-basins connected by a stream network and further delineates each sub-basin into hydrologic response units (HRUs), which consist of unique combinations of land cover, slope, and soil type [8]
Summary
Water resources are planned and regulated on a river basin scale so that the future design and evaluation of management practices depend on the total hydrologic and biogeochemical performance of the basin instead of singular hydrologic units [1,2,3]. Assessment Tool (SWAT) is one of these watershed models designed for simulating long-term water quantity and quality as impacted by land use and climate changes and best management practices at large-scale watersheds [6]. It is a semiphysical and semidistributed model accounting for major hydrological and biogeochemical processes significant at large spatial scale (small to large watersheds) and medium to large temporal scale (daily to monthly) [8,9,10]. It is so designed that no or minimal calibration efforts may be taken to provide reasonable simulation results at large-scale watersheds given accurate inputs including weather data, topographic and soil characteristics, and land use and management information [8,14,15]
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