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Combined use of groundwater dating, chemical, and isotopic analyses to resolve the history and fate of nitrate contamination in two agricultural watersheds, Atlantic coastal plain, Maryland

The history and fate of groundwater nitrate (NO3-) contamination were compared in 2 small adjacent agricultural watersheds in the Atlantic coastal plain by combined use of chronologic (CCl2F2, 3H), chemical (dissolved solids, gases), and isotopic (delta 15N, delta 13C, delta 34S) analyses of recharg...

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Bibliographic Details
Published in:Water resources research 1995-09, Vol.31 (9), p.2319-2339
Main Authors: Böhlke, J. K., Denver, J. M.
Format: Article
Language:English
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Summary:The history and fate of groundwater nitrate (NO3-) contamination were compared in 2 small adjacent agricultural watersheds in the Atlantic coastal plain by combined use of chronologic (CCl2F2, 3H), chemical (dissolved solids, gases), and isotopic (delta 15N, delta 13C, delta 34S) analyses of recharging groundwaters, discharging groundwaters, and surface waters. The results demonstrate the interactive effects of changing agricultural practices, groundwater residence times, and local geologic features on the transfer of NO(3-) through local flow systems. Recharge dates of groundwaters taken in 1990-1992 from the surficial aquifer in the Chesterville Branch and Morgan Creek watersheds near Locust Grove, Maryland, ranged from pre-1940 to the late 1980's. When corrected for localized denitrification by use of dissolved gas concentrations, the dated waters provide a 40-year record of the recharge rate of NO3-, which increased in both watersheds by a factor of 3-6, most rapidly in the 1970's. The increase in groundwater NO3- over time was approximately proportional to the documented increase in regional N fertilizer use, and could be accounted for by oxidation and leaching of about 20-35% of the fertilizer N. Groundwaters discharging upward beneath streams in both watersheds had measured recharge dates from pre-1940 to 1975, while chemical data for second-order reaches of the streams indicated average groundwater residence times in the order of 20+ years. At the time of the study, NO3-discharge rates were less than NO3- recharge rates for at least two reasons: (1) discharge of relatively old waters with low initial NO3- concentrations, and (2) local denitrification. In the Chesterville Branch watershed, groundwaters remained oxic throughout much of the surficial aquifer and discharged relatively unaltered to the stream, which had a relatively high NO3- concentration (9-10 mg/L as N).
ISSN:0043-1397
1944-7973
DOI:10.1029/95WR01584