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Albitized microcline grains of post-depositional and probable detrital origins in Brøttum Formation sandstones (Upper Proterozoic), Sparagmite Region of southern Norway

Published online by Cambridge University Press:  01 May 2009

S. Morad
Affiliation:
Department of Mineralogy and Petrology, Institute of Geology, Uppsala University, Box 555, S-751 22 Uppsala, Sweden

Abstract

Untwinned albite (Ab99.4An0.4Or0.2) grains, forming during diagenesis and very low-grade metamorphism, are common in sandstones of the Brøttum Formation (Upper Proterozoic) in the Sparagmite Region of southern Norway. These untwinned albite grains are usually clouded by vacuoles and tiny inclusions which are mostly made of carbonaceous material (although some albite grains also contain some combination of carbonates, quartz, phengite, chlorite, pyrite, halite and anatase). The presence of microcline grains replaced partly by albite indicates that the albite grains are pseudomorphs after microcline. Chessboard albite which occurs in the Brøttum Formation is suggested to be detrital in origin.

Type
Articles
Copyright
Copyright © Cambridge University Press 1988

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References

Bailey, E. N. & Stevens, R. E. 1960. Selective staining of K-feldspar and plagioclase on rock slabs and thin sections. American Mineralogist 45, 1020–25.Google Scholar
Barth, T. F. W. 1938. Progressive metamorphism of sparagmite rocks of southern Norway. Norsk Geologisk Tidskrift 18, 5465.Google Scholar
Bjørlykke, K. 1966. Sedimentary petrology of the Sparagmites of the Rena district, S. Norway. Norges Geologiske Undersøkelse 238, 553.Google Scholar
Boles, J. R. 1982. Active albitization of plagioclase, Gulf Coast Tertiary. American Journal of Science 282, 165–80.CrossRefGoogle Scholar
Chou, L. & Wollast, R. 1985. Steady-state kinetics and dissolution mechanisms of albite. American Journal of Science 285, 963–93.CrossRefGoogle Scholar
de Vore, G. W. 1959. The surface chemistry of feldspars as an influence on their decomposition products. Clays and Clay Minerals 6, 2641.Google Scholar
Englund, J.-O. 1966. Sparagmittgruppens bergarter ved Favang, Gudbrandsdalen: en sedimentologisk og tektonisk undersøkelse. Norges Geologiske Undersøkelse 238, 55103.Google Scholar
Englund, J.-O. 1972. Sedimentological and structural investigations of the Hedmark Group in the Tretten-Øyer-Fåberg District Gudbrandsdalen. Norges Geologiske Undersøkelse 276, 59 pp.Google Scholar
Englund, J.-O. 1973 a. Geochemistry and mineralogy of pelitic rocks from the Hedmark Group and the Cambro-Ordovician sequence, southern Norway. Norges Geologiske Undersøkelse 286, 60 pp.Google Scholar
Englund, J.-O. 1973 b. Stratigraphy and structure of the Ringebu–Vinstra District, Gudbrandsdalen; with a short analysis of the western part of the Sparagmite Region in southern Norway. Norges Geologiske Undersøkelse 293, 58 pp.Google Scholar
Ferry, J. M. 1984. A biotite isograde in south-central Maine, U.S.A.: mineral reactions, fluid transfer, and heat transfer: Journal of Petrology 25, 871–93.CrossRefGoogle Scholar
Gold, P. B. 1987. Textures and geochemistry of authigenic albite from Miocene sandstones, Louisiana Gulf Coast. Journal of Sedimentary Petrology 57, 353362.Google Scholar
Grabezhev, A. I. 1972. Near-fracture albitization in the fine-grained zone of microcline-albite pegmatites in the Urals. Geochemistry international 8, 859–62.Google Scholar
Kastner, M. 1971. Authigenic feldspars in carbonate rocks. American Mineralogist 56, 1403–42.Google Scholar
Kastner, M. & Siever, R. 1979. Low temperature feldspars in sedimentary rocks. American Journal of Science 279, 435–79.CrossRefGoogle Scholar
Lajoie, J. 1973. Albite of secondary origin in Charny sandstones, Québec: a discussion. Journal of Sedimentary Petrology 43, 575–7.CrossRefGoogle Scholar
Land, L. S. 1987. The major ion chemistry of saline brines in sedimentary basins. In Physics and Chemistry Porous Media II (ed. Banavar, J. R., Koplik, J. J., Winkler, K. W.), pp. 160–79. American Institute of Physics Conference Proceedings, 154.Google Scholar
Land, L. S. & Milliken, K. L. 1981. Feldspar diagenesis in the Frio Formation, Brazoria County, Texas Gulf Coast. Geology 9, 314–18.2.0.CO;2>CrossRefGoogle Scholar
Land, L. S., Milliken, K. L. & McBride, E. F. 1987. Diagenetic evolution of Cenozoic sandstones, Gulf of Mexico sedimentary basin. Sedimentary Geology 50, 195225.CrossRefGoogle Scholar
Land, L. S. & Prezbindowski, D. R. 1981. The origin and evolution of saline formation water, Lower Cretaceous carbonates, south-central Texas, U.S.A. Journal of Hydrology 54, 5174.CrossRefGoogle Scholar
Mather, J. D. 1970. The biotite isograde and the lower green-schist facies in the Dalradian rocks of Scotland. Journal of Petrology 11, 253–75.CrossRefGoogle Scholar
Merino, E. 1975. Diagenesis in Tertiary sandstones from Kettleman North Dome California. I. diagenetic mineralogy. Journal of Sedimentary Petrology 45, 320–36.Google Scholar
Middleton, G. V. 1972. Albite of secondary origin in Charny sandstones, Québec. Journal of Sedimentary Petrology 42, 341349.Google Scholar
Moody, J. B., Jenkins, J. E. & Meyer, D. 1985. An experimental investigation of the albitization of plagioclase. Canadian Mineralogist 23, 583–96.Google Scholar
Moore, D. E. & Liou, J. 1979. Chessboard-twinned albite from Franciscan Metaconglomerates of the Diablo Range, California. American Mineralogist 64, 329–36.Google Scholar
Morad, S. 1986. Albitization of K-feldspar grains in Proterozoic arkoses and greywackes from southern Sweden. Neues Jahrbuch für Mineralogie Monatshefte 1986, 145–56.Google Scholar
Nystuen, J. P. 1982. Late Proterozoic basin evolution on the Baltoscandian Craton: the Hedmark Group, southern Norway Norges Geologiske Undersøkelse, 375, 74 pp.Google Scholar
Ogunyomi, O., Martin, R. F. & Hesse, R. 1981. Albite of secondary origin in Charny Sandstones, Québec: A revaluation. Journal of Sedimentary Petrology 51, 597606.Google Scholar
Roedder, E. 1984. Fluid inclusions. Mineralogical Society of America. Reviews in Mineralogy 12, 646 pp.Google Scholar
Saigal, G. C., Morad, S., Bjørlykke, K., Egeberg, P. K. & Aagaard, P. 1988. Diagenetic albitization of detrital K-feldspars in Jurassic, Lower Cretaceous and Tertiary clastic reservoir rocks from offshore Norway. I. Textures and origin. Journal of Sedimentary Petrology (in press).Google Scholar
Stel, H. 1984. Hydrothermal processes in mylonitic rocks at the NW edge of the Grong culmination, central Norway. Geologica Ultraaiectina 27, 115 pp.Google Scholar
Sillanpää, J. 1986. Mineral chemistry study of progressive metamorphism in calcareous schists from Ankarvattnet, Swedish Caledonides. Lithos 19, 141–52.CrossRefGoogle Scholar
Strand, T. 1951. The Sel and Vågå map areas. Norges Geologiske Undersøkelse 178, 166 pp.Google Scholar
Velbel, M. A. 1983. A dissolution-reprecipitation mechanism for the pseudomorphous replacement of plagioclase feldspar by clay minerals during weathering. Science Géologiue Mémoire I, 139–47.Google Scholar
Walker, T. R. 1984. Diagenetic albitization of potassium feldspar in Arkosic sandstones. Journal of Sedimentary Petrology 54, 316.Google Scholar
Wang, G., Banno, S. & Takeuchi, K. 1986. Reactions to define the biotite isograd in the Ryoke metamorphic belt, Kii Peninsula, Japan. Contribution to Mineralogy and Petrology 93, 917.CrossRefGoogle Scholar