Intrinsic Bioremediation of Petroleum Hydrocarbons in a Gas Condensate-Contaminated Aquifer

A study was designed to determine if the intrinsic bioremediation of gas condensate hydrocarbons represented an important fate process in a shallow aquifer underlying a natural gas production site. For over 4 yr, changes in the groundwater, sediment, and vadose zone chemistry in the contaminated por...

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Bibliographic Details
Published in:Environmental science & technology 1999-08, Vol.33 (15), p.2550-2560
Main Authors: Gieg, Lisa M, Kolhatkar, Ravindra V, McInerney, Michael J, Tanner, Ralph S, Harris, Steve H, Sublette, Kerry L, Suflita, Joseph M
Format: Article
Language:English
Subjects:
02 PETROLEUM
020900 - Petroleum- Environmental Aspects
ALKYLATED AROMATICS
Applied sciences
AQUIFERS
AROMATICS
BENZENE
BIODEGRADATION
Biological and physicochemical properties of pollutants. Interaction in the soil
Bioremediation
CHEMICAL REACTIONS
Chemistry
Contamination
DECOMPOSITION
Earth sciences
Earth, ocean, space
ENERGY SOURCES
Engineering and environment geology. Geothermics
Exact sciences and technology
FOSSIL FUELS
FUELS
HYDROCARBONS
OIL SPILLS
ORGANIC COMPOUNDS
PETROLEUM
Pollution
Pollution, environment geology
REMEDIAL ACTION
Soil and sediments pollution
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Summary:A study was designed to determine if the intrinsic bioremediation of gas condensate hydrocarbons represented an important fate process in a shallow aquifer underlying a natural gas production site. For over 4 yr, changes in the groundwater, sediment, and vadose zone chemistry in the contaminated portion of the aquifer were interpreted relative to a background zone. Changes included decreased dissolved oxygen and sulfate levels and increased alkalinity, Fe(II), and methane concentrations in the contaminated groundwater, suggesting that aerobic heterotrophic respiration depleted oxygen reserves leaving anaerobic conditions in the hydrocarbon-impacted subsurface. Dissolved hydrogen levels in the contaminated groundwater indicated that sulfate reduction and methanogenesis were predominant biological processes, corroborating the geochemical findings. Furthermore, 10−1000-fold higher numbers of sulfate reducers and methanogens were enumerated in the contaminated sediment relative to background. Putative metabolites were also detected in the contaminated groundwater, including methylbenzylsuccinic acid, a signature intermediate of anaerobic xylene decay. Laboratory incubations showed that benzene, toluene, ethylbenzene, and each of the xylene isomers were biodegraded under sulfate-reducing conditions as was toluene under methanogenic conditions. These results coupled with a decrease in hydrocarbon concentrations in the contaminated sediment confirm that intrinsic bioremediation contributes to the attenuation of hydrocarbons in this aquifer.
ISSN:0013-936X
1520-5851
DOI:10.1021/es981349d