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References (42)
-
B. Jones, A. Oldershaw, G. Narbonne (1979)
Nature and origin of rubbly limestone in the upper Silurian Read Bay Formation of Arctic CanadaSedimentary Geology, 24
-
A. Kendall (1977)
ORIGIN OF DOLOMITE MOTTLING IN ORDOVICIAN LIMESTONES FROM SASKATCHEWAN AND MANITOBABulletin of Canadian Petroleum Geology, 25
-
D. Morrow (1990)
Synsedimentary dolospar cementation: a possible Devonian example in the Camsell Formation, Northwest Territories, Canada1Sedimentology, 37
-
D. Morrow (1978)
Dolomitization of lower Paleozoic burrow-fillingsJournal of Sedimentary Research, 48
-
L. Railsback, S. Ackerly, T. Anderson, J. Cisne (1990)
Palaeontological and isotope evidence for warm saline deep waters in Ordovician oceansNature, 344
-
Ibrahim Mirsal, H. Zankl (1985)
Some phenomenological aspects of carbonate geochemistry. The control effect of transition metals — ReplyGeologische Rundschau, 77
-
B. Brown, G. Farrow (1978)
Recent Dolomitic Concretions of Crustacean Burrow Origin from Loch Sunart, West Coast of ScotlandJournal of Sedimentary Research, 48
-
S. Burns, J. Mckenzie, C. Vasconcelos (2000)
Dolomite formation and biogeochemical cycles in the PhanerozoicSedimentology, 47
-
Reddy Reddy (1977)
Crystallization of calcium carbonate in the presence of trace concentrations of phosphorous?containing anionsJournal of Crystal Growth, 41
-
D. Zenger (1996)
Dolomitization of the "C" zone, Red River Formation (Upper Ordovician) in deep core, Williston Basin, Richland County, eastern MontanaRocky Mountain Geology, 31
-
N. Chow, F. Longstaffe (1995)
Dolomites of the Middle Devonian Elm Point Formation, Southern Manitoba: Intrinsic Controls on Early DolomitizationBulletin of Canadian Petroleum Geology, 43
-
J. Hudson (1977)
Stable isotopes and limestone lithificationJournal of the Geological Society, 133
-
D. Over (1990)
Trace metals in burrow walls and sediments, Georgia Bight, USAIchnos-an International Journal for Plant and Animal Traces, 1
-
Ibrahim Mirsal, H. Zankl (1985)
Some phenomenological aspects of carbonate geochemistry. The control effect of transition metalsGeologische Rundschau, 74
-
A. Kendall (1975)
Anhydrite Replacements of Gypsum (Satin-Spar) Veins in the Mississippian Caprocks of Southeastern SaskatchewanCanadian Journal of Earth Sciences, 12
-
D. Wright (1997)
An Organogenic Origin for Widespread Dolomite in the Cambrian Eilean Dubh Formation, Northwestern ScotlandJournal of Sedimentary Research, 67
-
Y. Lith, R. Warthmann, C. Vasconcelos, J. Mckenzie (2003)
Sulphate‐reducing bacteria induce low‐temperature Ca‐dolomite and high Mg‐calcite formationGeobiology, 1
-
Michael Reddy (1977)
Crystallization of calcium carbonate in the presence of trace concentrations of phosphorus-containing anions: I. Inhibition by phosphate and glycerophosphate ions at pH 8.8 and 25°CJournal of Crystal Growth, 41
-
(1996)
Trace Fossils, Biology and Taphonomy, 2nd edn. Unwin-Hyman, London -
J. Rogers, P. Bennett, G. Macpherson (2003)
Microbial precipitation of dolomite in groundwater -
H. Machel, E. Mountjoy (1986)
Chemistry and Environments of Dolomitization —A ReappraisalEarth-Science Reviews, 23
-
Zenger Zenger (1996b)
Dolomitization of the ?C? zone, Red River Formation (Upper Ordovician) in deep core, Williston Basin, Richland County, eastern MontanaContributions to Geology, 31
-
R. Reitsema (1980)
Dolomite and nahcolite formation in organic rich sediments: isotopically heavy carbonatesGeochimica et Cosmochimica Acta, 44
-
F. Lippmann (1973)
Sedimentary Carbonate Minerals -
K. Tobin, K. Walker (1997)
Ordovician oxygen isotopes and paleotemperaturesPalaeogeography, Palaeoclimatology, Palaeoecology, 129
-
P. Baker, M. Kastner (1981)
Constraints on the formation of sedimentary dolomite.Science, 213 4504
-
D. Zenger (1996)
Dolomitization patterns in widespread “Bighorn Facies” (Upper Ordovician), Western Craton, USACarbonates and Evaporites, 11
-
R. Murray, F. Lucia (1967)
Cause and Control of Dolomite Distribution by Rock SelectivityGeological Society of America Bulletin, 78
-
Gingras Gingras, Pemberton Pemberton, Mendoza Mendoza, Henk Henk (1999)
Modeling fluid flow in trace fossils; assessing the anisotropic permeability of Glossifungites surfacesPetroleum Geoscience, 5
-
M. Gingras, S. Pemberton, C. Mendoza, F. Henk (1999)
Assessing the anisotropic permeability of Glossifungites surfacesPetroleum Geoscience, 5
-
S. Epstein, D. Graf, E. Degens (1964)
Oxygen Isotope Studies on the Origin of Dolomites -
(1971)
Ordovician and Silurian stratigraphy of the interlake area, Manitoba -
(1971)
Textures of calcitic cements formed during early diagenesis, Fraser Delta, British Columbia. In Carbonate Cements (ed. Bricker OP) -
R. Warthmann, Y. Lith, C. Vasconcelos, J. Mckenzie, A. Karpoff (2000)
Bacterially induced dolomite precipitation in anoxic culture experimentsGeology, 28
-
Beales Beales (1953)
Dolomitic mottling in Palliser (Devonian) Limestone, Banff and Jasper National Parks, AlbertaAmerican Association of Petroleum Geologists Bulletin, 37
-
Y. Lith, R. Warthmann, C. Vasconcelos, J. Mckenzie (2003)
Microbial fossilization in carbonate sediments: a result of the bacterial surface involvement in dolomite precipitationSedimentology, 50
-
M. Slaughter, R. Hill (1991)
The influence of organic matter in organogenic dolomitizationJournal of Sedimentary Research, 61
-
R. Dimitrakopoulos, K. Muehlenbachs (1987)
Biodegradation of petroleum as a source of 13C-enriched carbon dioxide in the formation of carbonate cementChemical Geology: Isotope Geoscience Section, 65
-
Hudson Hudson (1977)
Stable isotopes and limestone lithificationGeological Society of London, 133
-
B. Sander, J. Kalff (1993)
Factors controlling bacterial production in marine and freshwater sedimentsMicrobial Ecology, 26
-
A. Gunatilaka, A. Al-Zamel, D. Shearman, A. Reda (1987)
A spherulitic fabric in selectively dolomitized siliciclastic crustacean burrows, northern KuwaitJournal of Sedimentary Research, 57
-
G. Gladyshev (1953)
Dolomitic Mottling in Palliser (Devonian) Limestone, Banff and Jasper National Parks, AlbertaAAPG Bulletin
- Publisher
- Wiley
- Copyright
- Copyright © 2004 Wiley Subscription Services, Inc., A Wiley Company
- ISSN
- 1472-4677
- eISSN
- 1472-4669
- DOI
- 10.1111/j.1472-4677.2004.00022.x
- Publisher site
- See Article on Publisher Site
Abstract
ABSTRACT The formation of dolomite is generally explained using models that reflect larger‐scale processes that describe the relationship between the supply and transport of Mg, and geochemical conditions that are amenable to the formation of dolomite. However, heterogeneities in the substrate, such as those made by bioturbating infauna, may play a more important role in dolomitization than has been previously considered. Burrow‐facilitated dolomitization is evident in the Ordovician Tyndall Stone (Red River Group, Selkirk Formation) of central Canada. The diagenetic fabrics present are attributed to dolomitizing fluids that both flowed through and evolved within burrow networks. Petrographic analysis suggests that two phases of dolomite formation took place. The first formed a fine‐grained, fabric‐destructive type that probably accompanied early burial; the second is a fine‐ to medium‐grained, locally sucrosic dolomite that is interpreted to have precipitated during later burial. Isotopic analysis supports the proposed paragenetic history: (1) an apparent linking of the stable isotopes 13C and 18O strongly suggests that the micrite matrix formed during very early diagenesis and was derived from seawater; (2) the initial phase of dolomitization is potentially microbially mediated, as evidenced by the enrichment of 13C; and (3) isotopic values for the second generation of dolomite reflect the mixing of ground water and resorbed early dolomite. This paper conceptualizes the physical and chemical conditions required for the formation of dolomite in association with burrow fabrics. The proposed model reveals a composite of biological and inorganic reactions that demonstrates the interdependence of sediment fabric, organic content and microbial interactions in the development of burrow‐mottled dolomitic limestone. It is suggested that where burrow‐associated dolomite occurs, it is most likely to develop in two stages: first, the byproducts of the degradation of organic material in burrows locally increase the permeability and porosity around burrow fabrics in shallow diagenetic depositional environments; and, second, the passing of burrowed media into deeper dysaerobic sediment is accompanied by the establishment of fermenting micro‐organisms whose byproducts mediate dolomitization.
Journal
Geobiology – Wiley
Published: Jan 1, 2004