Runoff Curve Numbers at the Agricultural Field‐Scale and Implications for Continuous Simulation Modeling |
| |
| Authors: | Paul M McGinley Adam T Freihoefer Randy S Mentz |
| |
| Institution: | 1. College of Natural Resources, University of Wisconsin‐Stevens Point, , Stevens Point, Wisconsin, 54481Paper No. JAWRA‐12‐0155‐P of the Journal of the American Water Resources Association (JAWRA).;2. Bureau of Water Quality, Wisconsin Department of Natural Resources, , Madison, Wisconsin;3. Pioneer Farm, University of Wisconsin‐Platteville, , Platteville, Wisconsin |
| |
| Abstract: | This study used monitoring in the waterways of agricultural fields to understand the use of the runoff curve number (CN) in continuous simulation models. The CN has a long history as a design tool for estimating runoff volumes for large, single storms on small watersheds, but its use in continuous simulation models to describe runoff from smaller storms and relatively small areas is more recent and controversial. We examined 788 nonwinter rainfall events on four agricultural fields over five years (2004‐2008) during which runoff was generated in 87 events. The largest 20 runoff events on each field generated approximately 90% of the total runoff volume. The runoff event CNs showed an inverse correlation with storm depth that could not consistently be explained by previous precipitation. We review how small areas of higher runoff generation within larger areas will systematically increase the apparent CN of the larger area as the storm size decreases. If this variation is not incorporated into a model explicitly, continuous simulation modelers must understand that when source areas are aggregated or when runoff generation is spatially variable, the overall CN is not unique when smaller storms are included in the calibration set. |
| |
| Keywords: | nonpoint source pollution runoff curve number agricultural hydrologic modeling |
|
|
