Deep vadose zone hydrology demonstrates fate of nitrate in eastern San Joaquin Valley

Thomas Harter; Yuksel S Onsoy; Katrin Heeren; Michelle Denton; Gary Weissmann; Jan W Hopmans; William R Horwath

doi:10.3733/ca.v059n02p124

California Agriculture (Apr 2005)

Deep vadose zone hydrology demonstrates fate of nitrate in eastern San Joaquin Valley

Thomas Harter,
Yuksel S Onsoy,
Katrin Heeren,
Michelle Denton,
Gary Weissmann,
Jan W Hopmans,
William R Horwath

Affiliations

Thomas Harter: T. Harter is Associate Groundwater Quality Hydrologist (UC Cooperative Extension), Department of Land, Air and Water Resources, UC Davis
Yuksel S Onsoy: Y.S. Onsoy is consultant and Doctoral Candidate, UC Davis
Katrin Heeren: K. Heeren is freelance geologist in environmental education, Germany
Michelle Denton: M. Denton is consultant and obtained a master's degree in hydrologic studies, Department of Land, Air and Water Resources, UC Davis
Gary Weissmann: G. Weissmann is Assistant Professor of Hydrogeology, Department of Geological Sciences, Michigan State University
Jan W Hopmans: J.W. Hopmans is Professor of Vadose Zone Hydrology, Department of Land, Air and Water Resources, UC Davis.
William R Horwath: W.R. Horwath is Associate Professor of Soil Biogeochemistry, Department of Land, Air and Water Resources, UC Davis.

DOI: https://doi.org/10.3733/ca.v059n02p124
Journal volume & issue: Vol. 59, no. 2
pp. 124 – 132

Abstract

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The sustainability of water resources is key to continued prosperity in the San Joaquin Valley and California. The vadose zone is an often-ignored layer of wet but unsaturated sediments between the land surface and the water table. It plays an important role in groundwater recharge and in controlling the flux and attenuation of nitrate and other potential groundwater contaminants. In a former orchard at the UC Kearney Research and Extension Center, we investigated the processes that control the movement of water, nitrate and other contaminants through the deep vadose zone. These processes were found to be controlled by the alluvial sedimentary geology of the vadose zone, which is highly heterogeneous. This heterogeneity should be considered when interpreting soil and deep vadose zone monitoring data and assessing of the leaching potential of agricultural chemicals. The transport of contaminants through the vadose zone may be significantly faster than previously assumed, while denitrification is likely limited or insignificant in the oxic, alluvial vadose zone of the eastern San Joaquin Valley.

Published in California Agriculture

ISSN: 0008-0845 (Print); 2160-8091 (Online)
Publisher: University of California Agriculture and Natural Resources
Country of publisher: United States
LCC subjects: Agriculture
Website: https://californiaagriculture.org/

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