Improving understanding of mixed-land-use watershed suspended sediment regimes: Mechanistic progress through high-frequency sampling

Elliott Kellner; Jason A Hubbart

doi:10.1016/j.scitotenv.2017.04.052

Improving understanding of mixed-land-use watershed suspended sediment regimes: Mechanistic progress through high-frequency sampling

Sci Total Environ. 2017 Nov 15:598:228-238. doi: 10.1016/j.scitotenv.2017.04.052. Epub 2017 Apr 22.

Authors

Elliott Kellner¹, Jason A Hubbart²

Affiliations

¹ University of Missouri, School of Natural Resources, 203 ABNR Building, Columbia, MO 65211, USA; West Virginia University, Institute of Water Security and Science, Davis College, Schools of Agriculture and Food, and Natural Resources. 3107 Agricultural Sciences Building, Morgantown, WV 26506, USA. Electronic address: Elliott.Kellner@mail.wvu.edu.
² West Virginia University, Institute of Water Security and Science, 3109 Agricultural Sciences Building, Morgantown, WV 26506, USA; West Virginia University, Davis College, Schools of Agriculture and Food, and Natural Resources. 3109 Agricultural Sciences Building, Morgantown, WV 26506, USA. Electronic address: Jason.Hubbart@mail.wvu.edu.

PMID: 28441601
DOI: 10.1016/j.scitotenv.2017.04.052

Abstract

Given the importance of suspended sediment to biogeochemical functioning of aquatic ecosystems, and the increasing concern of mixed-land-use effects on pollutant loading, there is an urgent need for research that quantitatively characterizes spatiotemporal variation of suspended sediment dynamics in contemporary watersheds. A study was conducted in a representative watershed of the central United States utilizing a nested-scale experimental watershed design, including five gauging sites (n=5) partitioning the catchment into five sub-watersheds. Hydroclimate stations at gauging sites were used to monitor air temperature, precipitation, and stream stage at 30-min intervals during the study (Oct. 2009-Feb. 2014). Streamwater grab samples were collected four times per week, at each site, for the duration of the study (Oct. 2009-Feb. 2014). Water samples were analyzed for suspended sediment using laser particle diffraction. Results showed significant differences (p<0.05) between monitoring sites for total suspended sediment concentration, mean particle size, and silt volume. Total concentration and silt volume showed a decreasing trend from the primarily agricultural upper watershed to the urban mid-watershed, and a subsequent increasing trend to the more suburban lower watershed. Conversely, mean particle size showed an opposite spatial trend. Results are explained by a combination of land use (e.g. urban stormwater dilution) and surficial geology (e.g. supply-controlled spatial variation of particle size). Correlation analyses indicated weak relationships with both hydroclimate and land use, indicating non-linear sediment dynamics. Suspended sediment parameters displayed consistent seasonality during the study, with total concentration decreasing through the growing season and mean particle size inversely tracking air temperature. Likely explanations include vegetation influences and climate-driven weathering cycles. Results reflect unique observations of spatiotemporal variation of suspended sediment particle size class. Such information is crucial for land and water resource managers working to mitigate aquatic ecosystem degradation and improve water resource sustainability in mixed-land-use watersheds globally.

Keywords: Experimental watershed study; Land use impacts; Laser particle diffraction; Particle size; Suspended sediment.