Microbial Abundance and Activity in a Low-Conductivity Aquifer System in East-Central Texas

Microbial Abundance and Activity in a Low-Conductivity Aquifer System in East-Central Texas

The influence of sediment properties and groundwater geochemistry on microbial abundance and activity was examined in a Gulf Coast aquifer system. Three boreholes were drilled into the sands, silts, clays, and lignite of the Eocene Yegua formation, and wells were installed in all water-bearing sands...

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Bibliographic Details
Published in:Microbial ecology Vol. 35; no. 3; pp. 224 - 234
Main Authors: D. P. Martino, E. L. Grossman, G. A. Ulrich, K. C. Burger, J. L. Schlichenmeyer, J. M. Suflita, Ammerman, J. W.
Format: Journal Article
Language:English
Published: New York, NY Springer-Verlag New York Inc 01-05-1998
Springer
Subjects:
Animal, plant and microbial ecology
Aquifers
Bacteria
Biological and medical sciences
Fundamental and applied biological sciences. Psychology
Geochemistry
Groundwater
Microbial ecology
Microorganisms
Oxidation
Sand
Sediments
Sulfates
Sulfides
Various environments (extraatmospheric space, air, water)
United States
North America
Texas
America
Microbial activity
Sulfate-reducing bacteria
Sulfatoreduction
Vertical distribution
Environmental factor
Hydraulic conductivity
Biogeochemical cycle
Sulfur cycle
Microbial biomass
Aquifers
Freshwater environment
Carbon cycle
Pyrite
Bacteria
Population density
Ground water
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Summary:The influence of sediment properties and groundwater geochemistry on microbial abundance and activity was examined in a Gulf Coast aquifer system. Three boreholes were drilled into the sands, silts, clays, and lignite of the Eocene Yegua formation, and wells were installed in all water-bearing sands. Total numbers of microorganisms ranged from 106to 108cells g-1dry weight (${\rm gdw}^{-1}$), and viable counts ranged from 0 to 106cells${\rm gdw}^{-1}$. The highest densities of anaerobic heterotrophs and sulfate-reducing bacteria (SRB; 105and 106cells${\rm gdw}^{-1}$, respectively) were measured in the deepest aquifer sands (28-31 m), even though the total organic carbon content was very low. Rates of anaerobic H2, lactate, and formate consumption were also high in aquifer sands, relative to the other strata. The higher microorganism numbers and activities in the aquifer sediments likely reflect the importance of increased electron donor and acceptor transport in higher hydraulic conductivity sands, relative to other strata. The presence of sulfate and near absence of other electron acceptors ( O2, NO3 -, and Fe3+), absence of methanogens, high numbers of SRB, and relatively high sulfate reduction activity suggest that sulfate reduction is the dominant terminal electron-accepting process in the deep aquifer. In contrast to aerobic Atlantic Coastal Plain sediments, aquifer sediments at 30 m in this east-central Texas aquifer contain greater numbers of anaerobes than aerobes. Low pH and high sulfate contents argue for oxidation of pyrite in or near the shallow aquifer. This pyrite oxidation supplies sulfate to deeper aquifers. Pyrite from the deep aquifer sediments, with the greatest abundance and activity of SRB, is too enriched in^{34}{\rm S}$(up to 58‰) to have formed from modern or typical groundwater sulfate. Overall, our results suggest that the resident microbiota are capable of cycling carbon and sulfur in the aquifer, but probably without substantial remineralization of pyrite in the formation.
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ISSN:0095-3628
1432-184X
DOI:10.1007/s002489900078