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Controls on Carbonate Mineralogy and Crystal Morphology:
Classic and recent papers
Amjad, Z., Pugh, J., and Reddy, M., 1997, Kinetic inhibition of calcium carbonate crystal growth in the presence of natural and synthetic organic inhibitors: Abstracts of Papers of The American Chemical Society, v. 214, p.143.
Berner, R.A., 1975, The role of magnesium in the crystal growth of calcite and aragonite from sea water: Geochim. Cosmochim. Acta, v.39, p. 489-504.
Bosak, T., and Newman, D.K., 2005, Microbial kinetic controls on calcite morphology in supersaturated solutions: Journal of Sedimentary Research, v. 75, p. 190-199.
Brooks, R., Clark, L.M., and Thurston, E.F., 1950, Calcium carbonate and its hydrates: Royal Society of London Philosophical Transactions, v. 243, p. 145-167.
Buchardt, B., Seaman, P., Stockmann, G., Vous, M., Wilken, U., Düwel, L., Kristiansen, Aa., Jenner, C., Whiticar, M.J., Kristensen, R.M., Petersen, G.H., and Thorbjørn, L., 1997, Submarine columns of ikaite tufa. Nature, v. 390, p. 129-130.
B. Buchardt, C. Israelson, P. Seaman & G. Stockmann, 2001, Ikaite tufa towers in Ikka Fjord, Southwest Greenland: Their formation by mixing of seawater and alkaline spring water. Journal of Sedimentary Research, v. 71, p. 176-189.
Burton, E.A., and Walter, L.M., 1987, Relative precipitation rates of aragonite and Mg calcite from seawater: Temperature or carbonate ion control?: Geology, v. 15, p. 111-114.
Burton E.A., and Walter, L.M., 1990, The role of pH in phosphate inhibition of calcite and aragonite precipitation rates in seawater: Geochim. Cosmochim. Acta, v. 54, p. 797-808.
Burton, E.A., 1993, Controls on marine carbonate cement mineralogy: review and reassessment: Chem Geol., v. 105, p. 163-179.
Chafetz, H.S., Wilkinson, B.H., and Love, K.M., 1985, Mineralogy and composition of non-marine carbonate cements in near-surface settings, in N. Schneidermann and P.M. Harris, eds., Carbonate Cements: SEPM. Sp. Pub. 36, p. 337-347.
Davis, K.J., Dove, P.M., and De Yoreo, J.J., 2000, The role of Mg2+ as an impurity in calcite grooeth: Science. v. 290, p. 1134-1137.
Deleuze, M., and Brantley, S.L., 1997, Inhibition of calcite crystal growth by Mg2+ at 100¡C and 100 bars: Influence of growth regime: Geochimica et Cosmochimica Acta, v. 61, p. 1475-1485.
Dickson, J.A.D., 1993, Crystal growth diagrams as an aid to interpreting the fabric of calcite aggregates: Journal of Sedimentary Petrology, v. 63, p. 1-17.
Fern‡ndez-D’az, L., Putnis, A., Prieto, M., and Putnis, C., 1996, The role of magnesium in the crystallization of calcite and aragonite in a porous medium: Journal of Sedimentary Research, v.66, p. 482-491.
Folk, R.L., 1974, The natural history of crystalline calcium carbonate: effect of magnesium content and salinity: Jour. Sed. Petrol., v. 44, p. 40-53.
Given, R.K., and Wilkinson, B.H., 1985, Kinetic control of morphology, composition, and mineralogy of abiotic sedimentary carbonates: Jour. Sed. Petrol., v. 55, p. 109- 119.
Gonzales, L.A., Carpenter, S.J., and Lohmann, K.C, 1992, Inorganic calcite morphology: roles of fluid chemistry and fluid flow: Journal of Sedimentary Petrology, v. 62, p. 382-399. (Disc. & Reply JSP v. 63 p. 560-563 and 1160-1164)
Gonzalez, L.A, and Lohmann, K.C, 1988, Controls on mineralogy and composition of spelean carbonates: Carlsbad Caverns, New Mexico: in James, N.P., and Choquette, P.W., eds., Paleokarst: New York, Springer-Verlag, p. 81-101.
Jones, B., and Kahle, C.F., 1993, Morphology, relationship, and origin of fiber and dendrite calcite crystals: Jour. Sed. Petrol., v. 63, p. 1018-1031.
Johnston, J., Merwin, H.E., and Williamson, E.D., 1916, The several forms of calcium carbonate: American Journal of Science, v. 41, p. 473-512.
Lahann, R.W., 1978, A chemical model for calcite crystal growth and morphology control: Jour. Sed. Petrol., v. 48, p. 337-344.
Lebrón, I., and Suarez, D.L., 1996, Calcite nucleation and precipitation kinetics as affected by dissolved organic matter at 25°C and pH>7.5: Geochimica et Cosmochimica Acta, v. 60, p. 2765-2776.
Lebrón, I., and Suarez, D.L., 1998, Kinetics and mechanisms of precipitation of calcite as effected by PCO2 and organic ligands at 25°C: Geochimica et Cosmochimica Acta, v. 62, p. 405-416.
Lippman, F., 1973, Sedimentary Carbonate Minerals: New York, Springer Verlag, 228 p.
Mirsal, I., and Zankl, H., 1985, Some phenomenological aspects of carbonate geochemistry; the control effect of transition metals: Geologische Rundschau, vol.74, p.367-377.
Morse, J.W., Wang, Q., and Tsio, M.Y., 1997, Influences of temperature and Mg:Ca ratio on CaCO3 precipitates from seawater: Geology, v. 25, p. 85-87.
Paquette, J., Vali, H., and Mucci, A., 1996, TEM study of Pt-C replicas of calcite overgrowths precipitated from electrolyte solutions: Geochimica et Cosmochimica Acta, v. 60, p. 4689-4699.
Reeder, R.J., ed., 1983, Carbonates: Mineralogy and Chemistry: Revs. Min., v. 11, 394 p.
Searl, A., 1991, Sawtooth zoned calcite cements in Dinantian grainstones from South Wales (U.K.): Jour. Sed. Petrol., v. 61, p. 195-201.
Titiloye, J.O., de Leeuw, N.H., and Parker, S.C., 1998, Atomistic simulation of the differences between calcite and dolomite surfaces: Geochimica et Cosmochimica Acta, v. 62, p. 2637-2641.
Walker, K.R., Jernigan, D.G., and Weber, L.J., 1990, Petrographic criteria for the recognition of marine, syntaxial overgrowths, and their distribution in geologic time: Carbonates and Evaporites, v. 5, p. 141-151.
Walter, L.M., 1986, Relative efficiency of carbonate dissolution and precipitation during diagenesis: a progress report on the role of solution chemistry, in Gautier, D.L. ed., Roles of Organic Matter in Sediment Diagenesis: Soc. Econ. Pal. Min. Sp. Pub. 38, p. 1-11.
Walter, L.M., and Hanor, J.S., 1979, Orthophosphate: effect on the relative stability of aragonite and magnesian calcite during early diagenesis: Jour. Sed. Petrol., v. 49, p. 937-944.
Zuddas, P., and Mucci, A., 1998, Kinetics of calcite precipitation from seawater: II. The influence of ionic strength: Geochimica et Cosmochimica Acta, v. 62, p. 757- 776.
Bates, N.R., and Brand, U., 1990, Secular variation in calcium carbonate mineralogy: an evaluation of ooid and micrite chemistries: Geologische Rundschau, v. 79, p. 27- 46.
Berner, R.A., 1987, Models for carbon and sulfur cycles and atmospheric oxygen: Application to Paleozoic geologic history: Amer. Jour. Sci., v. 287, p. 177-196.
Berner, R.A.,1991, A model for atmospheric CO2 over Phanerozoic time: American Journal of Science, v. 291, p. 339-376.
Berner, R.A., 1994, GEOCARB II: A revised model of atmospheric CO2 over Phanerozoic time: American Journal of Science, v. 294, p. 56-91.
Brass, G.W., Southam, J.R., and Peterson, W.H., 1982b, Warm saline bottom water in the ancient ocean: Nature, v. 296, p. 620-623.
Fischer, A.G., 1981, Climatic oscillations in the biosphere, in Nitecki, M., ed., Biotic Crises in Ecological and Evolutionary Time: New York, Academic Press, p. 103- 131. QH545.N3S65 1980
Fischer, A.G., 1982, Long-term climatic oscillations recorded in stratigraphy, in Berger, W., ed., Climate in Earth History: Washington, National Academy of Sciences, p. 97-104.
Frakes, L.A., 1979, Climates Throughout Geologic Time: Amsterdam, Elsevier Scientific Pub. Co., 310 p.
Frank, T.D., and Fielding, C.R., 2003, Marine origin for Precambrian, carbonate-hosted magnesite?: Geology, v. 31, p. 1101-1104.
Garrels, R.M., and Mackenzie, F.T., 1971, Evolution of Sedimentary Rocks: New York, W.W. Norton & Co., 397 p.
Given, R.K., and Wilkinson, B.H., 1987, Dolomite abundance and stratigraphic age: Constraints on rates and mechanisms of Phanerozoic dolostone formation: Jour. Sed. Petrology., v. 57, p. 1068-1078.
Hallam, A., 1984, Pre-Quaternary sea level changes: Ann. Rev. Earth Planet. Sci., v. 12, p. 205-243.
Hardie, L.A., 1996, Secular variation in seawater chemistry: An explanation for the coupled secular variation in the mineralogies of marine limestones and potash evaporites over the past 600 m.y.: Geology, v. 24, p. 279-283.
Heckel, P.H., 1974, Carbonate buildups in the geologic record, in Laporte, L.F., ed., Reefs in Space and Time: SEPM. Sp. Pub. 18, p. 90-154.
Holland, H.D., 1984, The Chemical Evolution of the Atmosphere and Oceans: Princeton, N.J., Princeton Univ. Press, 582 p.
Hudson J.D., and Anderson, T.F., 1989, Ocean temperatures and isotopic compositions through time: Royal Soc. Edinburgh Trans. (Earth Science) v. 80, p. 183-192.
James, N.P. & Bone, Y., 1989, Petrogenesis of Cenozoic, temperate water calcarenites, South Australia: A model for meteoric/shallow burial diagenesis of shallow water calcite sediments: Jour. Sed. Petrol., v. 59, p. 191-203.
Kiessling, W., 2001, Paleoclimatic significance of Phanerozoic reefs: Geology, v. 29, 751-754.
Lasemi, Z., and Sandberg, P.A., 1994, Temporal trends in the mineralogy of Phanerozoic micrite precursors: AAPG/SEPM Annual Meeting Abstracts p. 193.
Mackenzie, F.T., and Morse, J.W., 1992, Sedimentary carbonates through Phanerozoic time: Geochimica et Cosmochimica Acta, v. 56, p.3281-3295.
Mackenzie, F.T., and Pigott, J.D., 1981, Tectonic controls of Phanerozoic sedimentary rock cycling: Jo. Geol. Soc. London, v. 138, p. 183-196.
Martin, R.E., 1995, Cyclic and secular variation in microfossil biomineralization: clues to the biogeochemical evolution of Phanerozoic oceans: Global and Planetary Change, v. 11, p. 1-23.
Miller, K.G., Kominz, M.A., Brownng, J.V., Wright, J.D., Mountain, G.S., Katz, M.E., Sugarman, P.J., Cramer, B.S., Christie-Blick, N., and Pekar, S.F., 2005, The Phanerozoic record of global sea-level change: Science, v. 310, p. 1293-1298.
Railsback, L. B., 1989, Sea level, episodic dolomitization, and temporal trends in non- skeletal carbonate mineralogy: Geol. Soc. Amer. Abstracts w. Programs, v. 21, p. A139.
Railsback, L. B., 1990, Influence of changing deep ocean circulation on the Phanerozoic oxygen isotopic record: Geochimica et Cosmochimica Acta, v. 54, p. 1501-1509.
Railsback, L.B., 1993, Original mineralogy of Carboniferous worm tubes: Evidence for changing marine chemistry and biomineralization: Geology, v. 21, p. 703-706. Railsback, L. B., and Anderson, T. F., 1987, Control of Triassic seawater chemistry and temperature on the evolution of post-Paleozoic aragonite-secreting faunas: Geology, v. 15, p. 1002-1005.
Ronov, A.B., 1982, The Earth's sedimentary shell: quantitative patterns of its structure, compositions, and evolution: Int'l Geology Review, v. 24, p. 1313-1388 (Reprinted by Amer. Geol. Inst., Reprint Series V, 1983).
Sandberg, P.A., 1983, An oscillating trend in Phanerozoic non-skeletal mineralogy: Nature, v. 305, p. 19-22.
Sandberg, P.A., 1985, Nonskeletal aragonite and pCO2 in the Phanerozoic and Proterozoic, in Sundquist, E.T., and Broecker, W.S., eds., The Carbon Cycle and Atmospheric CO2: Natural Variations Archean to Present: American Geophysical Union Geophysical Monograph 32, p. 585-594.
Savin, S.M., 1977, History of the earth's surface temperature during the last 100 million years: Ann. Rev. Earth. Plan, Sci., v. 5, p. 319-335.
Stanley, S.M., Ries, J.B., and Hardie, L.A., 2002, Low-magnesium calcite produced by coralline algae in seawater of Late Cretaceous composition: Proc. Natl. Acad. Sci. USA, v. 99, p. 15323-15326.
Sumner, D.Y., and Grotzinger, J.P., 1996, Were kinetics of Archean calcium carbonate precipitation related to oxygen concentration?: Geology, v. 24, p. 119-122.
Taylor, P.D., and Allison, P.A., 1998, Bryozoan carbonates through space and time: Geology, v. 26, p. 459-462.
Vail, P.R., Mitchum, R.M., Jr., and Thompson, S., 1977, Seismic stratigraphy and global changes of sea level, part 4: Global cycles of relative changes in sea level, in Payton, C.E., ed., Seismic Stratigraphy-Applications to Hydrocarbon Exploration: AAPG Mem. 26, p. 83-97.
Webb, G.E., 1996, Was Phanerozoic reef history controlled by the distribution of non- enzymatically secreted reef carbonates (microbial carbonate and biologically induced cement)?: Sedimentology, v. 43, p. 947-971.
Wilkinson, B.H., 1979, Biomineralization, paleoceanography, and the evolution of calcareous marine organisms: Geology, v. 7, p. 524-527.
Wilkinson, B.H.,1988, Earth-surface cycling of divalent cations and the history of riverine-ridge Mg-Ca fluxes from mass-age data on Phanerozoic limestones and dolostones: Geol. Soc. Amer. Abs. w. Prog., v. 20, p. A329.
Wilkinson, B.H., and Algeo, T.J., 1989, Sedimentary carbonate record of calcium- magnesium cycling: Amer. Jo. Sci., v. 289, p. 1158-1194.
Wilkinson, B.H., and Given, R.K., 1986, Secular variation in abiotic marine carbonates: Constraints on Phanerozoic atmospheric carbon dioxide contents and oceanic Mg/Ca ratios: Jour. Geol., v. 94, p. 321-333.
Wilkinson, B.H., Owen, R.M., and Carroll, A.R., 1985, Submarine hydrothermal weathering, global eustasy, and carbonate polymorphism in Phanerozoic marine oolites: Jour. Sed. Petrol., v. 55, p. 171-183
Wilkinson, B.H., and Walker, J.C.G., 1989, Phanerozoic cycling of sedimentary carbonate: Amer. Jour. Sci., v. 289, p. 525-548.
Woods, A.D., Bottjer, D.J., Mutti, M., and Morrison, J., 1999, Lower Triassic sea-floor carbonate cements: Their origin and a mechanism for the prolonged biotic recovery from the end-Permian mass extinction: Geology, v. 27, p. 645-648.
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