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A finite element model for simulating runoff and soil erosion from mechanically treated agricultural lands: 2. Field validation and applications
Author(s) -
Sharda V. N.,
Singh Sita Ram,
Sastry G.,
Dhruvanarayana V. V.
Publication year - 1994
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1029/94wr00063
Subject(s) - surface runoff , environmental science , hydrology (agriculture) , runoff curve number , soil conservation , tillage , hydrograph , erosion , soil science , hydraulic conductivity , runoff model , geotechnical engineering , soil gradation , impervious surface , soil water , geology , agriculture , geography , geomorphology , ecology , archaeology , biology
The finite element model for simulation of runoff and soil erosion as developed by Sharda and Singh (this issue) is evaluated using data collected from agricultural land treated with major mechanical soil and water conservation measures, namely, contour bunding, graded bunding, bench terracing, and conservation bench terracing. The simulated and experimentally realized hydrographs and soil loss values are in reasonably good agreement for various measures. Probable reasons for discrepancies between the predicted and observed values are discussed. The model has the potential of being used on a single storm or a continuous basis provided the soil, crop, and climatic parameters are precisely known or estimated for a given location and for the period under consideration. The model logically simulates the effects of flow, topographic, soil, and crop parameters such as antecedent moisture level, roughness coefficient, saturated hydraulic conductivity, slope, depth of impoundment, size of outlet, longitudinal slope of the channel, vertical interval, and cropping management factor. The model is found to be quite sensitive to changes in roughness coefficient, rainfall excess rate, and cover management factor, and hence these parameters need to be assessed carefully in the field. The general applicability of the model as a planning tool for soil conservation measures and the scope for future development are also discussed.