Analysis of recharge-induced geochemical change in a contaminated aquifer

Recharge events that deliver electron acceptors such as O2, NO3, SO4, and Fe(3+) to anaerobic, contaminated aquifers are likely important for natural attenuation processes. However, the specific influence of recharge on (bio)geochemical processes in ground water systems is not well understood. The i...

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Bibliographic Details
Published in:Ground water 2005-07, Vol.43 (4), p.518-530
Main Authors: McGuire, J.T, Long, D.T, Hyndman, D.W
Format: Article
Language:English
Subjects:
Anaerobiosis
Aquifers
Biodegradation, Environmental
biogeochemistry
chlorinated solvents
Cluster Analysis
Contamination
Electrons
Factor Analysis, Statistical
Fresh Water - chemistry
Fuel Oils
Geochemistry
Groundwater
groundwater contamination
Groundwater flow
groundwater recharge
Hydrocarbons
Hydrocarbons, Chlorinated - chemistry
hydrochemistry
Hydrogen-Ion Concentration
Iron - analysis
organochlorine compounds
Oxidation-Reduction
petroleum
redox potential
Seasons
solvents
Sulfides - analysis
terminal electron-accepting processes
Water Pollutants, Chemical
Water Purification - methods
Water, Underground
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Summary:Recharge events that deliver electron acceptors such as O2, NO3, SO4, and Fe(3+) to anaerobic, contaminated aquifers are likely important for natural attenuation processes. However, the specific influence of recharge on (bio)geochemical processes in ground water systems is not well understood. The impact of a moderate-sized recharge event on ground water chemistry was evaluated at a shallow, sandy aquifer contaminated with waste fuels and chlorinated solvents. Multivariate statistical analyses coupled with three-dimensional visualization were used to analyze ground water chemistry data (including redox indicators, major ions, and physical parameters) to reveal associations between chemical parameters and to infer processes within the ground water plume. Factor analysis indicated that dominant chemical associations and their interpreted processes (anaerobic and aerobic microbial processes, mineral precipitation/dissolution, and temperature effects) did not change significantly after the spring recharge event of 2000. However, the relative importance of each of these processes within the plume changed. After the recharge event, the overall importance of aerobic processes increased from the fourth to the second most important factor, representing the variability within the data set. The anaerobic signatures became more complex, suggesting that zones with multiple terminal electron-accepting processes (TEAPs) likely occur in the same water mass. Three-dimensional visualization of well clusters showed that water samples with similar chemical associations occurred in distinct water masses within the aquifer. Water mass distinctions were not based on dominant TEAPs, suggesting that the recharge effects on TEAPs occurred primarily at the interface between infiltrating recharge water and the aquifer.
ISSN:0017-467X
1745-6584
DOI:10.1111/j.1745-6584.2005.0040.x