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1. |
Acknowledgments |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 3-3
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ISSN:0149-0451
DOI:10.1080/01490459009377889
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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2. |
Foreword |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 5-5
HenryL. Ehrlich,
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ISSN:0149-0451
DOI:10.1080/01490459009377890
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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3. |
In situ bioremediation of contaminated aquifers and subsurface soils |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 133-146
KatherineH. Baker,
DianeS. Herson,
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摘要:
Bioremediation, the use of microorganisms to detoxify and degrade hazardous wastes, is an emerging in situ treatment technology for the remediation of contaminated aquifers and subsurface soils. This technology depends upon the alteration of the physical/chemical conditions in the subsurface environment to optimize microbiological activity. As such, successful bioremediation depends not only upon an understanding of microbial degradation processes, but also upon an understanding of the complex interactions that occur between the contaminants, the subsurface environment, and the indigenous microbial populations at each site. At present, these interactions are poorly understood. Site‐specific evaluation and design therefore are essential for bioremediation. In this paper, we review microbiological, hydrological, and geochemical factors that should be considered in evaluating the appropriateness of bioremediation for hazardous waste‐contaminated aquifers and subsurface soils.
ISSN:0149-0451
DOI:10.1080/01490459009377891
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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4. |
Role of sulfate in microbial transformations of environmental contaminants: Chlorinated aromatic compounds |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 147-165
PatriciaJ. S. Colberg,
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摘要:
Despite recent progress made in describing microbial transformations that occur under anaerobic conditions, our understanding of the role sulfate‐reducing bacteria may play in the remediation of environmental contaminants is still very limited. The objective of this mini‐review is to summarize what is currently known of the metabolism of chlorinated aromatic compounds in the presence of sulfate. Sulfidogenic processes are discussed with respect to the thermodynamics of haloaromatic oxidation and to their potential use in the in situ bioremediation of hazardous organic wastes. A comprehensive listing is made of anaerobic transformations that involve both halogenated and nonhalogenated monoaromatic substrates by denitrifiers, dissimilatory iron‐reducing bacteria, and methanogenic consortia. In contrast to other anaerobic processes, studies involving sulfate‐mediated metabolism of hazardous organic compounds have been neglected; however, the recent success in defining methanogenic transformations, in particular, has enhanced expectations of defining an analogous role for sulfate‐reducing microbial communities in low redox environments that have become contaminated with hazardous substances.
ISSN:0149-0451
DOI:10.1080/01490459009377892
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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5. |
Methanogenic transformation of aromatic hydrocarbons and phenols in groundwater aquifers |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 167-200
Dunja Grbić‐Galić,
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摘要:
Fermentative and methanogenic bacteria have been found repeatedly as important members of microbial flora in anoxic zones of the subsurface—in pristine as well as in contaminated groundwater aquifers. These bacteria, which together with obligate proton reducers form complex methanogenic communities, are significant as decomposers of organic matter under conditions of exogenous electron acceptor depletion. Their metabolic activity has been demonstrated in laboratory microcosms derived from aquifer material, and also in the subsurface in situ. Methanogenic communities have been shown to transform numerous organic pollutants, or even to completely degrade these compounds with the production of carbon dioxide and methane. Depending on the chemical structure of the pollutant, such a compound can be used as an electron donor and a carbon/energy source for fermentative microorganisms (which is typically the case with highly reduced compounds); alternatively, a highly oxidized pollutant can be used as a potential electron acceptor or electron sink. This review addresses fermentative/methanogenic degradation of chlorinated and nonchlorinated aromatic hydrocarbons and phenols by subsurface microorganisms; for comparison, it briefly relates also other types of anaerobic transformations (under sulfate‐reducing, iron‐reducing, and denitrifying conditions). Furthermore, it outlines transformation pathways, those that are proposed as well as those that are already partially proved, for aromatic hydrocarbons and phenols under fermentative/methanogenic conditions; finally, it discusses the relevance of these processes to bioremediation of contaminated groundwater aquifers.
ISSN:0149-0451
DOI:10.1080/01490459009377893
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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6. |
Bioremediation of metal‐contaminated surface and groundwaters |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 201-223
CoraleL. Brierley,
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摘要:
Microorganisms immobilize, mobilize, or transform metals by extracellular precipitation reactions, intracellular accumulation, oxidation and reduction reactions, methylation and demethylation, and extracellular binding and complexation. Nearly all of these microbe/metal interactions occur within the wetlands approach to acid mine drainage treatment, a process that is rapidly gaining support as a low‐maintenance, cost‐effective approach to solving an important environmental problem. Several proprietary processes, which employ nonliving microorganisms that are immobilized in polymer matrixes, are entering the water treatment market. These processes take advantage of negatively charged functional groups on cell walls and exopolymers of microorganisms that bind cationic metals. These biosorbents effectively remove low concentrations (<1 to about 20 mg/L) of heavy metal cations in the presence of high concentrations of alkaline earth metals (Ca2+and Mg2+) and organic contaminants to levels lower than the U.S. National Drinking Water Standards. Immobilization of the biomass in polymer matrixes yields products that have substantial chemical and mechanical integrity. These immobilized products lend themselves to application in conventionally engineered systems such as up‐flow and down‐flow columns, expanded‐bed systems, dispersed‐bed systems, and low‐maintenance trough systems. Biosorption will probably play an important role in achieving the strict environmental standards now being enforced.
ISSN:0149-0451
DOI:10.1080/01490459009377894
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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7. |
Biotransformation of monoaromatic and chlorinated hydrocarbons at an aviation gasoline spill site |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 225-240
BarbaraH. Wilson,
JohnT. Wilson,
DonH. Kampbell,
BertE. Bledsoe,
JohnM. Armstrong,
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摘要:
A shallow water table aquifer under the U.S. Coast Guard Air Station at Traverse City, MI, has acclimated to the aerobic and anaerobic transformation of monoaromatic hydrocarbons (BTX) released from an aviation gasoline spill. The aquifer also exhibits reductive dechlorination of a chlorinated solvent spill adjacent to the aviation gasoline spill. The groundwater is buffered near neutrality. The aviation gasoline plume is methanogenic and the aquifer contains enough iron minerals to support significant iron solubilization. Field evidence of both aerobic and anaerobic biotransformation of monoaromatics was confirmed by laboratory studies of aquifer material obtained from the site. In the laboratory studies, the removal of the monoaromatics in the anaerobic material was rapid and compared favorably with removal in aerobic material. The kinetics of anaerobic removal of monoaromatics in the laboratory were similar to the kinetics at field scale in the aquifer. Biotransformation of the chlorinated solvents was not observed until late in the study, when daughter products from reductive dechlorination of the chlorinated solvents were identified by GC/MS.
ISSN:0149-0451
DOI:10.1080/01490459009377895
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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8. |
Biological detoxification of precious metal processing wastewaters |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 241-249
JamesL. Whitlock,
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摘要:
A biological treatment plant is utilized at the Homestake Mine in Lead, SD, to effect detoxification of a daily discharge of 4 million gallons of wastewater. The wastewater matrix requiring treatment contains cyanide, ammonia, toxic heavy metals, and a variable component of toxic chemicals associated with extractive metallurgy and mining operations. Rotating biological contactors (RBCs) are used to attach the biofilm. Cyanides and heavy metals concentrations are reduced by 95–98%. The treated discharge makes up as much as 60% of the total flow in a cold‐water trout fishery. This receiving stream, which remained lifeless for over 100 years as a mine drainage, has now become an established trout fishery and recently yielded a state record trout.
ISSN:0149-0451
DOI:10.1080/01490459009377896
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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9. |
Further readings in geomicrobiology |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 251-257
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PDF (492KB)
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ISSN:0149-0451
DOI:10.1080/01490459009377897
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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10. |
Authors’ correction |
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Geomicrobiology Journal,
Volume 8,
Issue 3-4,
1990,
Page 259-259
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PDF (17KB)
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ISSN:0149-0451
DOI:10.1080/01490459009377898
出版商:Taylor & Francis Group
年代:1990
数据来源: Taylor
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