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Simulating Landscape Sediment Transport Capacity by Using a Modified SWAT Model
Author(s) -
Bonumá Nadia B.,
Rossi Colleen G.,
Arnold Jeffrey G.,
Reichert José M.,
Minella Jean P.,
Allen Peter M.,
Volk Martin
Publication year - 2014
Publication title -
journal of environmental quality
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.888
H-Index - 171
eISSN - 1537-2537
pISSN - 0047-2425
DOI - 10.2134/jeq2012.0217
Subject(s) - swat model , watershed , sediment , environmental science , soil and water assessment tool , hydrology (agriculture) , deposition (geology) , erosion , sediment transport , wepp , soil science , geology , soil conservation , streamflow , drainage basin , geography , geomorphology , geotechnical engineering , agriculture , cartography , machine learning , computer science , archaeology
Sediment delivery from hillslopes to rivers is spatially variable and may lead to long‐term delays between initial erosion and related sediment yield at the watershed outlet. Consideration of spatial variability is important for developing sound strategies for water quality improvement and soil protection at the watershed scale. Hence, the Soil and Water Assessment Tool (SWAT) was modified and tested in this study to simulate the landscape transport capacity of sediment. The study area was the steeply sloped Arroio Lino watershed in southern Brazil. Observed sediment yield data at the watershed outlet were used to calibrate and validate a modified SWAT model. For the calibration period, the modified model performed better than the unaltered SWAT2009 version; the models achieved Nash–Sutcliffe efficiency (NSE) values of 0.7 and −0.1, respectively. Nash–Sutcliffe efficiencies were less for the validation period, but the modified model's NSE was higher than the unaltered model (−1.4 and −12.1, respectively). Despite the relatively low NSE values, the results of this first test are promising because the model modifications lowered the percent bias in sediment yield from 73 to 18%. Simulation results for the modified model indicated that approximately 60% of the mobilized soil is deposited along the landscape before it reaches the river channels. This research demonstrates the modified model's ability to simulate sediment yield in watersheds with steep slopes. The results suggest that integration of the sediment deposition routine in SWAT increases accuracy in steeper areas while significantly improving its ability to predict the spatial distribution of sediment deposition areas. Further work is needed regarding (i) improved strategies for spatially distributed sediment transport measurements (for improving process knowledge and model evaluation) and (ii) extensive model tests in other well instrumented experimental watersheds with differing topographic configurations and land uses.