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Simulation of Long-Term Water Erosion in Rainfed Croplands of Eastern Washington  Public Access Limited Time

Published by the American Society of Agricultural and Biological Engineers, St. Joseph, Michigan www.asabe.org

Citation:  Journal of the ASABE. 67(1): 193-206. (doi: 10.13031/ja.15623) @2024
Authors:   Mugal Samrat Dahal, Joan Wu, Mariana Dobre, Robert P. Ewing
Keywords:   Inland Pacific Northwest, Soil erosion by water, Temporal trend, WEPP.

Highlights

Water erosion in the inland Pacific Northwest was modeled with WEPP for the past (1940–1982) and present (1983–2020).

Water erosion decreased from past to present in the study watersheds.

Major factors are increased adoption of conservation practices and decrease in large precipitation events.

Abstract. Water erosion is an ongoing problem in eastern Washington due to its hilly terrain, highly erodible silt loam soils, rain on thawing soil, and the prevalence of conventional tillage. The region is characterized by a Mediterranean-type climate with warm, dry summers and cool, wet winters. Three distinct precipitation zones, with annual totals low (<380 mm), intermediate (380–460 mm), and high (>460 mm), dictate the area‘s crop rotations. A unique 43-year (1940–1982) dataset of winter erosion measured on multiple agricultural fields in Whitman County, eastern Washington, by Verle Kaiser, a USDA Soil Conservation Service agronomist, showed annual erosion rates averaging 53.8 Mg ha−1, far exceeding the current Natural Resources Conservation Service tolerable limit of 11 Mg ha−1 yr–1 for the soils in the area. Kaiser‘s field data allowed us to compare the historical field-measured erosion rates with those simulated by the WEPP (Water Erosion Prediction Project) model. Anthropogenic factors, such as tillage and crop rotation, change with time. Conservation tillage, including reduced- and no-till, has been increasingly adopted in eastern Washington since the mid-1980s. The specific objectives of this study were to (1) apply the WEPP model to simulate soil erosion in eastern Washington and evaluate the interactive effects of climate and management, in addition to topography and soil, on water erosion in the study area, and (2) compare the simulation results with Kaiser‘s historical field dataset and elucidate the long-term soil erosion trend. The WEPPcloud interface was used to delineate a watershed within each precipitation zone of the study area. Climate inputs were divided into two periods: the past (1939–1982) and the present (1983–2020). Erosion has noticeably decreased from the past to the present, with WEPP simulated annual erosion averaging 13.5, 34.5, and 52.6 Mg ha−1 for the past, and 9.5, 14.1, and 15.5 Mg ha−1 for the present, in the selected watersheds in the low-, intermediate-, and high-precipitation zones, respectively. The decreasing trend was primarily due to the increased adoption of conservation tillage and crop rotation, as well as a decrease in the number of high-intensity precipitation events in the present climate.

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