Location: Southeast Watershed Research
Project Number: 6602-13000-026-00
Start Date: Feb 07, 2012
End Date: Feb 06, 2017
This project will provide new knowledge on the effects of soil and water management on water quality, hydrology, and ecosystems services of agricultural watersheds in the Gulf-Atlantic Coastal Plain. Existing and new gauged watersheds form the core research site. The watersheds are characterized by intensive agriculture in upland areas and riparian forests along stream channels. Riparian areas provide baseflow from an alluvial aquifer and storage for storm runoff from adjacent upland areas. Although much of the research is done at smaller scales (plot, field, hillslope), the gauged watersheds allow both extrapolation and testing of technology at larger scales where all of the hydrologic processes important to an integrated landscape or watershed response are present. Cropping practices and patterns in the region are expected to change as bioenergy crops are introduced into crop rotations and on marginal lands. There are concerns about the potential water quantity and quality effects due to increased water demand, expanded acreages, increased inputs, and increased variability in weather and climate. New knowledge is needed on the effects of intensified production on water and soil at multiple spatial scales. Ecosystem services derived from agricultural landscapes, and the potential for conservation practices to enhance these services, also need quantification. The research will quantify: a) processes controlling erosion and chemical transport; b) effects on these processes of new and existing conservation practices at multiple scales; and c) effects of watershed management on water resources and ecosystem services. Research information will be used to better represent these processes in state of the science models. Variable rate rainfall simulation will be used to quantify the effects of extreme rainfall events on sediment and chemical transport and will provide new data to modify and test models to better represent extreme events. Tracer injection techniques will provide new information on flow rates for shallow groundwater and will improve models of field scale transport. The smaller scale studies will provide new information that will enhance understanding at the field and watershed level. Watershed scale hydrology and water quality data before and after bioenergy crop establishment will provide direct measures of their effects when integrated into land management. Field surveys combined with modeling will be used to determine the effects of distribution of conservation practices, water withdrawals, ponds, and irrigation uses on water quantity and quality. Comparisons of urban and agricultural water quality and quantity will serve as a direct measure of an ecosystem service from agriculture. Remote sensing tools will be used to determine how the ecosystem services soil carbon and water holding capacity are related to aboveground biomass production.