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Na biotite and intermediate Na-K biotite in schists from the Betic Cordilleras (Spain)

Published online by Cambridge University Press:  01 January 2024

María Dolores Ruiz Cruz
María Dolores Ruiz Cruz*
Affiliation:
Departamento de Química Inorgánica, Cristalografía y Mineralogía, Facultad de Ciencias, Universidad de Málaga, 29071 Málaga, Spain
*
*E-mail address of corresponding author: [email protected]
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Abstract

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Submicroscopic intergrowths of K biotite, Na biotite and intermediate Na-K biotite from a schist near Málaga (Betic Cordilleras, Spain) were discovered using high-resolution transmission electron microscopy and analytical electron microscopy. The sample was also studied with X-ray diffraction, electron microprobe analysis, and scanning electron microscopy. Scanning electron microscopy revealed that the Na-enriched biotite is concentrated in albite-rich microdomains, albite being partially replaced by biotite. These images also revealed that both K and Na-K biotite grains appear locally retrograded to kaolinite. Transmission electron microscopic data indicated that K biotite, Na biotite and Na-K biotite form parallel or subparallel packets with interfaces parallel to the basal planes of biotite. Potassium biotite forms thick packets, chemically homogeneous, with a basal spacing of 10.1 Å. Sodium biotite also occurs as chemically homogeneous stacks of layers with a 9.78 Å periodicity. Sodium-K biotite shows, on the contrary, variable composition and basal spacings intermediate between K and Na biotites. Analytical electron microscopic data revealed important chemical differences between Na and K biotites, which affect both the tetrahedral and the octahedral sheets. Both electron microprobe analysis and analytical electron microscopy indicated that the trioctahedral micas show relatively low interlayer occupancy, suggesting the presence of H3O+ replacing the interlayer cations. Partial hydration of biotite explains the presence of a weak 14 Å reflection in the X-ray patterns. Both chemical and textural data suggested that these trioctahedral micas grew during a common prograde metamorphic episode, the phases with intermediate composition probably being metastable.

Keywords

Betic CordillerasEMPANa biotiteK biotiteSEMTEM/AEMVermiculiteXRD
Type
Research Article
Information
Clays and Clay Minerals , Volume 52 , Issue 5 , October 2004 , pp. 603 - 612
Copyright
Copyright © 2004, The Clay Minerals Society

References

Brown, G. Brindley, G.W., Brindley, G.W. and Brown, G., (1980) X-ray procedures for clay mineral identification Crystal Structures of Clay Minerals and their X-ray Identification London Mineralogical Society 305360.Google Scholar
Cabella, R. Gazzotti, M. and Luccetti, G., (1997) Loveringite and baddeleyite in layers of chromian spinel from the Bracco ophiolitic unit, northern Apennines, Italy The Canadian Mineralogist 35 899908.Google Scholar
Carman, J.H., (1974) Synthetic sodium phlogopite and its two hydrates: stabilities, properties, and mineralogic implications American Mineralogist 59 261273.Google Scholar
Deer, W.A. Howie, R.A. and Zussman, J., (1976) Rock Forming Minerals. Sheet Silicates London Longman 270 pp.Google Scholar
Dempster, T.J. and Jackson, R.A., (1996) Na-biotite in Dalradian pelitic schists, Angus Scottish Journal of Geology 32 173177 10.1144/sjg32020173.Google Scholar
Egeler, C.G. and Simon, O.J., (1969) Orogenic evolution of the Betic Zone (Betic Cordilleras, Spain), with emphasis on the nappe structures Geologie en Mijnbouw 48 296305.Google Scholar
Frey, M., (1969) A mixed-layer paragonite/phengite of low-grade metamorphic origin Contributions to Mineralogy and Petrology 24 6365 10.1007/BF00398753.Google Scholar
Godard, G. and Smith, D.C., (1999) Preiswerkite and Na-(Mg, Fe)-margarite in eclogites Contributions to Mineralogy and Petrology 136 2032 10.1007/s004100050521.Google Scholar
Guidotti, C.V. and Bailey, S.W., (1984) Micas in metamorphic rocks Micas Washington D.C Mineralogical Society of America 357368 10.1515/9781501508820-014.Google Scholar
IGME, Mapa geológico de España (1:50000) Hoja de Málaga (1053) (1987) Madrid Centrode Publicaciones del Ministerio de Industria y Energía.Google Scholar
Jiang, W.T. and Peacor, D.R., (1993) Formation and modification of metastable intermediate sodium potassium mica, paragonite, and muscovite in hydrothermally altered metabasites from northern Wales American Mineralogist 78 782793.Google Scholar
Keusen, H.R. and Peters, T.j., (1980) Preiswerkite, an Al-rich trioctahedral sodium mica from the Geisspfad ultramafic complex (Penninic Alps) American Mineralogist 65 11341137.Google Scholar
Livi, K.J.T. Veblen, D.R. and Ferry, J.M., (1988) Electron microscope study of anchizone and epizone metamorphosed shales from the central Swiss Alps Geological Society of America, Abstracts with Programs 20 A244.Google Scholar
Lorimer, G.W. Cliff, G. and Wenk, H.R., (1976) Analytical electron microscopy of minerals Electron Microscopy in Mineralogy New York Springer Verlag 506519 10.1007/978-3-642-66196-9_38.Google Scholar
Melcher, F. Grum, W. Simon, G. Thalhammer, T.V. and Stumpfl, E.F., (1997) Petrogenesis of the ophiolitic giant chromite deposits of Kempirsai, Kazakhstan: a study of solid and fluid inclusions in chromite Journal of Petrology 38 14191458 10.1093/petroj/38.10.1419.Google Scholar
Meyer, J., (1983) The development of the high-pressure metamorphism in the Allalin metagabbro (Switzerland). High-pressure metamorphism: indicator of subduction and crustal thickening (abstract) Terra Cognita 3 187.Google Scholar
Miyashiro, A., (1994) Metamorphic Petrology London UCL Press 404 pp.Google Scholar
Peng, G.Y. Lewis, J. Lipin, B. McGee, J. Bao, P.S. and Wang, X.B., (1995) Inclusions of phlogopite and phlogopite hydrates in chromite from the Hongguleleng ophiolite in Xinjiang, northwest China American Mineralogist 80 13071316 10.2138/am-1995-11-1221.Google Scholar
Rieder, M. Cavazzini, G. D’yakonov, Y.S. Frank-Kamenetskii, V.A. Gottardi, G. Guggenheim, S. Koval, P.V. Müller, G. Neiva, A.M.R. Radoslovich, E.W. Robert, J.L. Sassi, F.P. Takeda, H. Weiss, Z. and Wones, D.R., (1998) Nomenclature of the micas Clays and Clay Minerals 46 586595 10.1346/CCMN.1998.0460513.Google Scholar
Ruiz Cruz, M.D., (1999) New data for metamorphic vermiculite European Journal of Mineralogy 11 533548 10.1127/ejm/11/3/0533.Google Scholar
Ruiz Cruz, M.D., (2001) Mixed-layer mica-chlorite in very low-grade metaclastites from the Malaguide Complex (Betic Cordilleras, Spain) Clay Minerals 36 307324 10.1180/000985501750539418.Google Scholar
Ruiz Cruz, M.D. and Novak, J., (2003) Metamorphic chlorite and ‘vermiculitic’ phases in mafic dikes from the Malaguide Complex (Betic Cordillera, Spain) European Journal of Mineralogy 15 6780 10.1127/0935-1221/2003/0015-0067.Google Scholar
Schreyer, W. Abraham, K. and Kulke, H., (1980) Natural sodium phlogopite coexisting with potassium phlogopite and sodium aluminium talc in a metamorphic evaporite sequence from Derrag, Tell Atlas, Algeria Contributions to Mineralogy and Petrology 74 223233 10.1007/BF00371692.Google Scholar
Shau, Y.-H. Feather, M.E. Essene, E.J. and Peacor, D.R., (1991) Genesis and solvus relations of submicroscopically intergrown paragonite and phengite in a blueschist from northern California Contributions to Mineralogy and Petrology 106 367378 10.1007/BF00324564.Google Scholar
Shultz, L.G. (1964) Quantitative interpretation of mineralogical composition from X-ray and chemical data for the Pierre Shale. US Geological Survey Professional Paper, 391-C, 31 pp.Google Scholar
Smith, D.C. and Smith, D.C., (1988) A review of the peculiar mineralogy of the ‘Norwegian coesite-eclogite province’, with crystal-chemical, petrological, geochemical and geodynamical notes and extensive bibliography Eclogites and Eclogite-facies Rocks Amsterdam Elsevier 1206.Google Scholar
Spear, F.S. Hazen, R.M. and Rumble, D., (1981) Wonesite: a new rock-forming silicate from the Post Pond Volcanics, Vermont American Mineralogist 66 100105.Google Scholar
Veblen, D.R., (1983) Exsolution and crystal chemistry of the sodium mica wonesite American Mineralogist 68 554565.Google Scholar
Yang, J.J. and Jahn, B.M., (2000) Deep subduction of mantle-derived garnet peridotites from the Su-Lu UHP metamorphic terrane in China Journal of Metamorphic Geology 18 167180 10.1046/j.1525-1314.2000.00249.x.Google Scholar
Yardley, B.W.D., (1989) An Introduction to Metamorphic Petrology Essex, England Longman 248 pp.Google Scholar