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TECHNICAL REPORTS

Vadose Zone Processes and Chemical Transport

Assessing Ground Water Vulnerability with the Type Transfer Function Model in the San Joaquin Valley, California

^a Scripps Institution of Oceanography, University of California San Diego, La Jolla, CA 92093-0224
^b Department of Geological and Environmental Sciences, Stanford University, Stanford, CA 94035-2115

^* Corresponding author (istewart{at}meteora.ucsd.edu).

Received for publication September 16, 2003. The recently developed type transfer function (TTF) simulation approach was applied to generate a regional-scale nonpoint-source ground water vulnerability assessment for the San Joaquin Valley, California. The computationally comparatively inexpensive TTF approach produces quantitative estimates of contaminant concentrations for large regional scales through characteristic functions based on different soil textures and their leaching properties. The TTF simulations employed an extensive soil and recharge database to estimate atrazine (1-chloro-3-ethylamino-5-isopropylamino-2,4,6-triazine) concentrations at a compliance depth of 3 m resulting from a surface application. Two different sets of TTFs with two different levels of upscaling were used for spatially uniform and distributed recharge estimates. Results show that estimated atrazine concentrations can be related to soil survey information. Areas with high potential vulnerability to atrazine leaching were found for soils with low organic carbon content and sandy loam and loam textures. Travel times for atrazine peak concentrations to the compliance depth ranged from 350 to 730 d. The extent of areas with estimated atrazine concentrations above the maximum contaminant level was less extensive when uniform annual recharge values were used. Simulated TTF concentrations were highest for eastern Fresno County, a vulnerability pattern that is also supported by field observations. The TTF modeling approach is shown to be a useful tool for quantitative pesticide leaching estimates at regional scales significantly larger than those of previous studies.

Abbreviations: MCL, maximum contaminant level • NPS, nonpoint source • TTF, type transfer function

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This Issue in Journal of Environmental Quality

JEQ 2004 33: 1177-1182. [Full Text]  

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