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Geomicrobiology Journal Volume 1, 1979 - Issue 4
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Original Articles

Sulfate reduction rates in Georgia marshland soils

G. W. Skyring Baas Becking Geobiological Laboratory, P.O. Box 378, Canberra City, A.C.T., 2601, Australia
,
R. L. Oshrain Department of Microbiology, University of Georgia, Athens, Georgia, 30601
&
W. J. Wiebe Department of Microbiology, University of Georgia, Athens, Georgia, 30601; CSIRO Coastal Ecology Program, Box 20, North Beach, Western Australia, 6020
Pages 389-400 | Published online: 28 Jan 2009

Citations (28)

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Read on this site (2)

G. W. Skyring. (1987) Sulfate reduction in coastal ecosystems. Geomicrobiology Journal 5:3-4, pages 295-374.
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R. Hallberg, A.-G. Engvall & T. Wadsten. (1984) Corrosion of Copper Lightning Conductor Plates. British Corrosion Journal 19:2, pages 85-88.
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Articles from other publishers (26)

Jung-Ho Hyun, April C. Smith & Joel E. Kostka. (2007) Relative contributions of sulfate- and iron(III) reduction to organic matter mineralization and process controls in contrasting habitats of the Georgia saltmarsh. Applied Geochemistry 22:12, pages 2637-2651.
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Carla M. Koretsky, Philippe Van Cappellen, Thomas J. DiChristina, Joel E. Kostka, Kristi L. Lowe, Charles M. Moore, Alakendra N. Roychoudhury & Eric Viollier. (2005) Salt marsh pore water geochemistry does not correlate with microbial community structure. Estuarine, Coastal and Shelf Science 62:1-2, pages 233-251.
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Yuch-ping Hsieh, Chou-her Yang & Jinan Feng. (1998) Sulfate reduction and a molybdate-induced soluble nitrogen flush in sediments during incubation. Soil Biology and Biochemistry 30:13, pages 1799-1804.
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K. Alef. 1995. Methods in Applied Soil Microbiology and Biochemistry. Methods in Applied Soil Microbiology and Biochemistry 271 310 .
L.R. Gardner, B.R. Smith & W.K. Michener. (1992) Soil evolution along a forest-salt marsh transect under a regime of slowly rising sea level, southeastern United States. Geoderma 55:1-2, pages 141-157.
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Leonard Robert Gardner & Ian Lerche. (1990) Simulation of sulfur diagenesis in anoxic marine sediments using rickard kinetics for FeS and FeS2 formation. Computers & Geosciences 16:4, pages 441-460.
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Graham W. Skyring & John Bauld. 1990. Advances in Microbial Ecology. Advances in Microbial Ecology 461 498 .
J.H. Whitcomb, R.D. Delaune & W.H. PatrickJr.Jr.. (1989) Chemical oxidation of sulfide to elemental sulfur: its possible role in marsh energy flow. Marine Chemistry 26:3, pages 205-214.
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H. Rodger Harvey, Robert D. Fallon & John S. Patton. (1989) Methanogenesis and microbial lipid synthesis in anoxic salt marsh sediments. Biogeochemistry 7:2, pages 111-129.
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R. Kelman Wieder & Gerald E. Lang. (1988) Cycling of inorganic and organic sulfur in peat from Big Run Bog, West Virginia. Biogeochemistry 5:2, pages 221-242.
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D.A. Pass, R. Dybdahl & M.M. Mannion. (1987) Investigations into the causes of mortality of the pearl oyster, Pinctada maxima (Jamson), in Western Australia. Aquaculture 65:2, pages 149-169.
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Mary Anne Carroll, Leroy E. Heidt, Ralph J. Cicerone & Ronald G. Prinn. (1986) OCS, H2S, and CS2 fluxes from a salt water marsh. Journal of Atmospheric Chemistry 4:3, pages 375-395.
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D.E. Padgett, Courtney T. Hackney & A.A. de la Cruz. (1986) Growth of filamentous fungi into balsa wood panels buried in North Carolina salt marsh sediments. Transactions of the British Mycological Society 87:1, pages 155-162.
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Howard J. Dicker & David W. Smith. (1985) Metabolism of low molecular weight organic compounds by sulfate-reducing bacteria in a Delaware salt marsh. Microbial Ecology 11:4, pages 317-335.
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Gary M. King, B.L. Howes & J.W.H. Dacey. (1985) Short-term endproducts of sulfate reduction in a salt marsh: Formation of acid volatile sulfides, elemental sulfur, and pyrite. Geochimica et Cosmochimica Acta 49:7, pages 1561-1566.
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D. C. Havill, A. Ingold & J. Pearson. (1985) Sulphide tolerance in coastal halophytes. Vegetatio 62:1-3, pages 279-285.
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Alan T. Herlihy & Aaron L. Mills. (1985) Sulfate Reduction in Freshwater Sediments Receiving Acid Mine Drainage. Applied and Environmental Microbiology 49:1, pages 179-186.
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D. C. Havill, A. Ingold & J. Pearson. 1985. Ecology of coastal vegetation. Ecology of coastal vegetation 279 285 .
Robert W. Howarth & Bo Barker Jrgensen. (1984) Formation of 35S-labelled elemental sulfur and pyrite in coastal marine sediments (Limfjorden and Kysing Fjord, Denmark) during short-term 35SO42? reduction measurements. Geochimica et Cosmochimica Acta 48:9, pages 1807-1818.
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George W. LutherIIIIII, Anne Giblin, Robert W. Howarth & Robert A. Ryans. (1982) Pyrite and oxidized iron mineral phases formed from pyrite oxidation in salt marsh and estuarine sediments. Geochimica et Cosmochimica Acta 46:12, pages 2665-2669.
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Gary M. King, M. J. Klug, R. G. Wiegert & A. G. Chalmers. (1982) Relation of Soil Water Movement and Sulfide Concentration to Spartina alterniflora Production in a Georgia Salt Marsh . Science 218:4567, pages 61-63.
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Gary M. King & M. J. Klug. (1982) Comparative Aspects of Sulfur Mineralization in Sediments of a Eutrophic Lake Basin. Applied and Environmental Microbiology 43:6, pages 1406-1412.
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Robert W. Howarth & John E. Hobbie. 1982. Estuarine Comparisons. Estuarine Comparisons 183 207 .
Gary M. King & W. J. Wiebe. (1980) Tracer Analysis of Methanogenesis in Salt Marsh Soils. Applied and Environmental Microbiology 39:4, pages 877-881.
Crossref
P. A. Trudinger, M. R. Walter & B. J. RalphJ. Bauld, R. V. Burne, L. A. Chambers, James Ferguson & G. W. Skyring. 1980. Biogeochemistry of Ancient and Modern Environments. Biogeochemistry of Ancient and Modern Environments 157 166 .
J. Bauld, R. V. Burne, L. A. Chambers, James Ferguson & G. W. Skyring. 1980. Biogeochemistry of Ancient and Modern Environments. Biogeochemistry of Ancient and Modern Environments 157 166 .

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