Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-21T17:12:48.788Z Has data issue: false hasContentIssue false

Precipitation of vaterite (CaCO3) during oil field drilling

Published online by Cambridge University Press:  05 July 2018

G. M. Friedman
Affiliation:
Department of Geology, Brooklyn College and Graduate School of the City University of New York, Brooklyn, New York 11210 and Northeastern Science Foundation, Rensselear Center of Applied Geology, 15 Third Street, P.O. Box 746, Troy, New York 12181-0746, USA
D. J. Schultz
Affiliation:
ARCO Oil & Gas Company, 2300 West Plano Parkway, Plano, Texas 75075, USA

Abstract

Vaterite, a CaCO3 polymorph, is a rare mineral that is said to be metastable under all known conditions. According to the literature, vaterite precipitated from carbonate solution recrystallizes spontaneously to calcite or aragonite. Yet vaterite has been identified in hard tissues of organisms, in gallstones, in contact metamorphic aureoles, in zones of thermal metamorphism, in a meteorite, and in cone-in-cone concretions. Newly precipitated vaterite has formed at the expense of carbonate rock in drilling fluids in wells of New York, Michigan, Nevada, Texas, and New Zealand. Petrographic examination reveals a light brown core of Ca3SiO5 surrounded by a colourless rim of vaterite. The δ18OPDB of New York vaterite is −12.4‰ and that of the Michigan vaterite is −17.6‰, which reflect the oxygen isotopic composition of meteoric freshwater used in drilling. The δ13CPDB value of −19.2‰ for New York vaterite and that of −17.6‰ for Michigan vaterite suggest that natural gas dissolved original carbonate in the subsurface. Drilling records from both wells indicate that natural gas was released into the drilling muds from the formations exposed at the time vaterite was encountered. Crossplots of the oxygen and carbon isotopic ratios overlap those of spurrite rocks in thermal metamorphic zones in Israel. A C-14 radiocarbon analysis of the Michigan vaterite gave an age of 953±39 yr. BP. 88.8±0.6% is modern carbon and 11.2% is dead carbon. Hence this carbon, and therefore the vaterite, is essentially modern. A sample of the New York vaterite yielded a modern age.

Type
Mineralogy
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1994

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Albright, J. H. (1971) Vaterite stability. Amer. Mineral, 56, 620–4.Google Scholar
Allen, R. C, Gavish, E. and Sanders, J. E. (1969) Aragonite-cemented sandstone from outer con-tinental shelf off Delaware Bay: submarine lithification mechanism yields product resembling beachrock. J. Sed. Petrol. 39, 136–49.Google Scholar
Avnimelech, M. (1964) Remarks of the occurrence of unusual, high temperature minerals in the so-called ‘mottled zone’ complex of Israel. Israel J. Earth-Sciences 13, 102–10.Google Scholar
Bar-Matthews, M., Matthews, A. and Ayalon, A. (1991) Environmental controls of speleothem mineralogy in a karstic dolomitic terrain (Soreg Cave, Israel). J. Geol. 99, 189-207Google Scholar
Bischoff, J. L. (1968) Catalysis, inhibition, and the calcite-Aragonite problem. II The vaterite-Ara-gonite transformation. Amer. J. Set, 266, 80–90.Google Scholar
Burke, W. H., Denison, R. E., Hetherington, E. A., Roepnick, R. B., Nelson, H. F. and Otto, J. B. (1982) Variation of sea water 87Sr/86Sr throughout Phanerozoic time. Geology, 10, 516-9Google Scholar
Cole, W. F. and Kroone, B. (1959) Carbonate minerals in hydrated portland cement. Nature, Brit. Assoc, BA, 57.Google Scholar
Deer, W. A., Howie, R. A. and Zussman, J. (1962) Rock-forming mineralsV. 5, Non-silicates. London, Longmans, Green, and Co. Ltd., 372 pp.Google Scholar
DuFresne, E. R. and Anders, E. (1962) On the retention of primordial noble gases in the Pesyanoe meteorite. Geochim. Cosmochim. Ada, 26, 251-62.Google Scholar
Fischer, R. B. and Ferguson, B. L. (1966) The precipitation of calcium carbonate. Indiana Acad. Sci., 75, 145–50.Google Scholar
Fong, C. C. R. (1981) Vaterite associated with cone-in-cone calcite of carbonate concretions in Ordovician black shales, Ile-Aux-Grues, Ile-Aux-Oies, Quebec Appalachians. Geol. Soc. America, Northeastern Section, Abstracts with Programs, 132-3.Google Scholar
Friedman, G. M. (1964) Early diagenesis and lithification in carbonate sediments. J. Sed. Petrol., 34, 777–813.Google Scholar
Friedman, G. M. (1965) On the origin of aragonite in the Dead Sea. Israel J. Earth Sci., 14, 79–85.Google Scholar
Friedman, G. M. (1968) Geology and Geochemistry of reefs, carbonate sediments and waters, Gulf of Aqaba (Elat), Red Sea. J. Sed. Petrol.,38, 895–919.Google Scholar
Friedman, G. M. (1987a) Deep-burial diagenesis: its implications for vertical movements of the crust, uplift of the lithosphere and isostatic unroofing -a review. Sed. Geology, 50, 67–94.Google Scholar
Friedman, G. M. (1987b) Vertical movements of the crust: Case histories from the northern Appala-chian basin. Geology, 15, 1130–3.Google Scholar
Friedman, G. M. (1991a) Methane-generated lithified dolostone of Holocene age: eastern Mediterranean. J. Sed. Petrol., 61, 188–94.Google Scholar
Friedman, G. M. (1991b) Vaterite rock, an unusual carbonate rock from the Lower Ordovician of the northern Appalachians. Geol. Soc. America, Abstracts with Programs, 1991 Annual meeting, San Diego, California, A412.Google Scholar
Friedman, G. M. and Sanders, J. E. (1967) Origin and occurrence of dolostones, 267—348 in Chilingar, G. V., Bissell, H. J. and Fairbridge, R. W., eds. Carbonate Rocks, Elsevier, Amsterdam, 471 pp.Google Scholar
Friedman, G. M., Schultz, D. J., Guo, B. and Sanders, J. E. (1993) Vaterite (an uncommon polymorph of Ca CO3): occurrences in boreholes demonstrate unexpected longevity. J. Sed. Petrol., 63, 663–4.Google Scholar
Gibson, R. E., Wyckoff, R. W. R. and Merwin, H. E. (1925) Vaterite and u calcium carbonate. Amer. J. Sci., 5th Series, 10, 325–33.Google Scholar
Hall, A. and Taylor, J. D. (1971) The occurrence of vaterite in gastropod egg-shells. Mineral. Mag., 38, 521–4.Google Scholar
Levins, A., Oshis, F. and Mateus, E. (1955) Condi-tions for the formation of different modifications of calcium carbonate. Latvijas PRS Zinatnu Akademijas Vestic 0002, 91, 87–100.Google Scholar
Johnston, J., Merwin, H. E. and Williamson, E. D. (1916) The several forms of calcium carbonate. Amer. J. Sci., 4th ser., 41, 473–512.Google Scholar
Kitano, Y., and Hood, D. W.(1965) The influence of organic material on the polymorphic crystallization of calcium carbonate. Geochim. Cosmochim. Ada, 29, 29–41.Google Scholar
Kolodny, Y. and Gross, S. (1974) Thermal meta-morphism by combustion of organic matter: isotopic and petrological evidence. J. Geol., 82, 489–506.Google Scholar
Lawrence, J. R. and Taviani, M. (1988) Extreme hydrogen, oxygen and carbon isotope anomalies in the pore waters and carbonates of the sediments and basalts from the Norwegian Sea: Methane and hydrogen from the mantle? Geochim. Cosmo-chim. Ada, 52, 2077–83.Google Scholar
Linck, G. (1903) Die Bildung der Oolithe und Rogensteine. Neues Jahrb. Beil, 16, 495–513.Google Scholar
Long, J. V. P. and McConnell, J. D. C. (1959) A mineralogical application of X-ray absorption microspectroscopy: the hydration of larnite. Mineral. Mag., 32, 117–27.Google Scholar
Lowenstam, H. A. and Abbott, D. P. (1975) Vaterite: A mineralization product of the hard tissues of a marine organism (Ascidiacea). Science, 188, 363–5.Google Scholar
Mayer, F. R. and Weineck, E. (1932) Die Verbreitung des Kalziumkarbonates im Tierreich unter beson-derer Berucksichtigung der Wirbellosen. Jena Zeitschr. Naturw., 66, 199–222.Google Scholar
Meyer, H. J. (1969) Structure und Fehlordnung des Vaterits. Zeits. Kristallogr., 128, 183–212.Google Scholar
McConnell, J. D. C. (1960) Vaterite from Ballycraigy, Larne, Northern Ireland. Mineral. Mag., 32, 535–44.Google Scholar
Nancollas, G. H. and Sawada, R. (1982) Formation of scales of calcium carbonate polymorphs: the influence of magnesium ion and inhibitors. J. Petrol. Tech., 645-52.Google Scholar
Ogino, T., Suzuki, T. and Sawada, R. (1987) The formation and transformation mechanism of calcium carbonate in water. Geochim. Cosmo-chim. Ada, 51, 2757–67.Google Scholar
Phemister, D. B., Aounsohn, M. G. and Pepensky, R. (1939) Variations in the cholesterol bile pigment and calcium salts contents of gallstones formed in gallbladder and in bile ducts with the degree of associated obstruction. Ann. Surg., 109, 161–86.Google Scholar
Plummer, N. L. and Busenberg, E. (1982) The solubilities of calcite, aragonite and vaterite in CO2-H2O solutions between 0 and 90°C, and an evaluation of the aqueous model for the system CaCO3-O2-H2O, Geochim. Cosmochim. Ada, 46, 1011–40.Google Scholar
Prien, E. L. and Frondel, C. (1947) Studies in urolithiasis; I. The composition of urinary calculi. J. Urology, 57, 949–94.Google Scholar
Ritger, S., Carson, B. and Suess, E. (1987) Methane-derived authigenic carbonates formed by subduc-tion-induced porewater expulsion along the Oregon/Washington margin. Geol. Soc. Amer. Bull, 98, 147–56.Google Scholar
Rodgers, A. L. (1983) Common ultrastructural features in human calculi. Micron Microscopia Ada, 14, 219–24.Google Scholar
Rowlands, D. L. G. and Webster, R. K. (1971) Precipitation of vaterite in lake water. Nature, Phys. and Set, 229, 158.Google Scholar
Schwartz, A., Eckart, D., O'Connell, J. and Francis, K. (1971) Growth of vaterite and calcite crystals in gels. Mat. Res. Bull., 6, 1341–4.Google Scholar
Shaikh, A. M and Shearman, D. J. (1986) On ikaite and the morphology of its pseudomorphs. Proceedings of the International Meeting ‘Geochemistry of the Earth Surface and Processes of Mineral Formation', Granada (Spain), pp.791-803.Google Scholar
Silk, S. T. (1970) Factors governing polymorph formation in calcium carbonate. Unpubl. Ph. D. thesis, New York Univ., 133pp.Google Scholar
Sommer, S. E. (1972) Cathodoluminescence of carbonates, 2 Geological applications. Chem. Geol, 9, 275–84.Google Scholar
Taylor, H. F. W. (1990) Cement chemistry. Academic Press, London, San Diego, New York. 479pp.Google Scholar
Turnbull, A. G. (1973) A thermochemical study of vaterite. Geochim. Cosmochim. Ada, 37, 1593–601.Google Scholar
Yamaguchi, T. and Murakawa, R. (1981) Preparation of spherical CaCO3 (vaterite) powder transition to calcite in water. Zairyo, 30, 856–60.Google Scholar