Effect of Microbially Induced Anoxia on Cr(VI) Mobility at a Site Contaminated with Hyperalkaline Residue from Chromite Ore Processing

This paper reports an investigation of microbially mediated Cr(VI) reduction in a hyperalkaline, chromium-contaminated soil-water system representative of the conditions at a chromite ore processing residue (COPR) site. Soil from the former surface layer that has been buried beneath a COPR tip for o...

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Published in:Geomicrobiology journal 2011-01, Vol.28 (1), p.68-82
Main Authors: Whittleston, R. A., Stewart, D. I., Mortimer, R. J. G., Ashley, D. J., Burke, I. T.
Format: Article
Language:English
Subjects:
Acetic acid
alkaliphile
anaerobe
Anoxia
bacteria
chromate
contaminated land
COPR
Iron
iron-reduction
microbial-reduction
Mobility
Nitrate reduction
Organic matter
pH effects
Precipitation
Soil
Soils (organic)
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cited_by cdi_FETCH-LOGICAL-a440t-bcbd6b2a9853b452669eac5b6f24d1948c04fa6807782dc1218279055a1363dc3
cites cdi_FETCH-LOGICAL-a440t-bcbd6b2a9853b452669eac5b6f24d1948c04fa6807782dc1218279055a1363dc3
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container_issue 1
container_start_page 68
container_title Geomicrobiology journal
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creator Whittleston, R. A.
Stewart, D. I.
Mortimer, R. J. G.
Ashley, D. J.
Burke, I. T.
description This paper reports an investigation of microbially mediated Cr(VI) reduction in a hyperalkaline, chromium-contaminated soil-water system representative of the conditions at a chromite ore processing residue (COPR) site. Soil from the former surface layer that has been buried beneath a COPR tip for over 100 years was shown to have an active microbial population despite a pH value of 10.5. This microbial population was able to reduce nitrate using an electron donor(s) that was probably derived from the soil organic matter. With the addition of acetate, nitrate reduction was followed in turn by removal of aqueous Cr(VI) from solution, and then iron reduction. Removal of ∼300 μM aqueous Cr(VI) from solution was microbially mediated, probably by reductive precipitation, and occured over a few months. Thus, in soil that has had time to acclimatize to the prevailing pH value and Cr(VI) concentration, microbially mediated Cr(VI) reduction can be stimulated at a pH of 10.5 on a time scale compatible with engineering intervention at COPR-contaminated sites.
doi_str_mv 10.1080/01490451.2010.498297
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subjects Acetic acid
alkaliphile
anaerobe
Anoxia
bacteria
chromate
contaminated land
COPR
Iron
iron-reduction
microbial-reduction
Mobility
Nitrate reduction
Organic matter
pH effects
Precipitation
Soil
Soils (organic)
title Effect of Microbially Induced Anoxia on Cr(VI) Mobility at a Site Contaminated with Hyperalkaline Residue from Chromite Ore Processing
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