New Version of Universal Soil Loss Equation to be Released Soon
The universal equation was created to help farmers estimate losses from soil erosion
Devised about 50 years ago by the scientists at the U.S. Department of Agriculture (USDA), the Universal Soil Loss Equation (USLE) was created to help farmers estimate losses from soil erosion, according to an article from Phys.Org.
Agricultural Research Service (ARS) scientists will soon release a new version that integrates models generated by cutting-edge computer technology, an updated soils database and new findings about erosion processes.
ARS is USDA's chief intramural scientific research agency, and this work supports the USDA priority of promoting international food security.
The original USLE used five factors to estimate the tons of soil lost per acre per year from the impact of raindrops and the flow of runoff water across fields disturbed by plowing and tilling. The formula is now used as the basis for estimating soil erosion wherever land is disturbed by farming or other human activities.
Every conservation plan written by the USDA Natural Resources Conservation Service has been based on soil-erosion calculations derived from USLE or its successors, the Revised Universal Soil Loss Equation (RUSLE) and version 2 (RUSLE2). Now, research leader Seth Dabney, who works at the ARS Watershed Physical Processes Research Unit in Oxford, Miss., is putting the finishing touches on an update of RUSLE2, which uses more intricate combinations of observation- and process-based science to produce soil erosion estimates.
New formulas have been added that can generate simulations of pasture plant lifecycles, which can be used to estimate the effects livestock and their different grazing patterns will have on soil erosion. The revised equations can also produce estimates of how much plant residue can be removed from crop and pasture lands for ethanol production without exposing the soil to excessive erosion.
RUSLE2's revised database contains information for the entire U.S. on climate and soil properties that affect erosion.