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Illite-Smectite Mixed-Layer Minerals in the Hydrothermal Alteration of Volcanic Rocks: II. One-Dimensional HRTEM Structure Images and Formation Mechanisms

Published online by Cambridge University Press:  01 January 2024

Takashi Murakami*
Affiliation:
Department of Earth and Planetary Science, The University of Tokyo, Tokyo 113-0033, Japan
Atsuyuki Inoue
Affiliation:
Department of Earth Sciences, Chiba University, Chiba 263-8522, Japan
Bruno Lanson
Affiliation:
LGIT-Maison des GéoScience, BP53, Université de J. Fourier, 38041 Grenoble Cedex 9, France
Alain Meunier
Affiliation:
Hydr ASA-UMR 6532 CNRS, Université de Poitiers, 40, av. du Recteur Pineau, 86022 Poitiers Cedex, France
Daniel Beaufort
Affiliation:
Hydr ASA-UMR 6532 CNRS, Université de Poitiers, 40, av. du Recteur Pineau, 86022 Poitiers Cedex, France
*
*E-mail address of corresponding author: [email protected]
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Abstract

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Smectite illitization was investigated in felsic volcaniclastic rocks from a drill core near the Kakkonda active geothermal system, Japan, using high-resolution transmission electron microscopy (HRTEM) that provided one-dimensional structure images of mixed-layer illite-smectite (I-S) minerals normal to [M0]. Simulated images of a rectorite-like structure revealed that smectite can be distinguished from illite in mixed-layer I-S by HRTEM if the basal spacing of smectite is larger than that of illite. The larger basal spacing of smectite, 1.3 nm under HRTEM, was obtained by intercalation of dodecylammonium ions into smectitic interlayers. In simulated and observed images normal to [hk0], tetrahedral (T) and octahedral (O) cation planes are imaged as dark lines, an illitic interlayer as a bright line, and a smectitic interlayer as a dark line sandwiched between two bright lines.

The samples are from depths of 435 m (5% I; R0), 635 m (35% I; R0), 656 m (62% I; R1), and 756 m (85% I; R3) where % I is the percentage of illite layers in a sample and R is the Reichweite parameter. Sample 435 consisted mostly of smectite, and illite layers occurred, though small in amount, as M1 units (module of type 1, defined as consisting of two polar T-O-T silicate layers with one central illitic interlayer and two, half smectitic interlayers at the outermost surface; the number corresponds to that of central illitic interlayers). The M1 units were dominant and isolated and consecutive smectite layers (>2) were present in sample 635. Sample 656 consisted mostly of packets of M1 units of 1 to 5 layers containing M2 to M5 units occasionally. Isolated or consecutive smectite layers (>2) were not present in 656. Illite layers occurred almost entirely as M1 units in samples 435, 635 and 656, and the number of M1 units increased with increase in % I. Sample 756 was characterized by the presence of M2 to M10 units accompanied by smectitic interlayers at the external surface and the absence of M1 units and isolated smectite layers. The HRTEM data strongly suggest that illitization in a hydrothermal system occurs by precipitation of M1 units for mixed-layer I-S minerals up to 60% I. This does not require the presence of precursor smectite. Illitization of I-S minerals with >60% I proceeds by precipitation of various types of Mn (n ⩾ 2) units. Illite occurs only as Mn (n ⩾ 1) units throughout illitization.

Type
Research Article
Copyright
Copyright © The Clay Minerals Society 2005

References

Altaner, S.P. and Ylagan, R.F., (1997) Comparison of structural models of mixed-layer illite/smectite and reaction mechanisms of smectite illitization Clays and Clay Minerals 45 517533 10.1346/CCMN.1997.0450404.CrossRefGoogle Scholar
Banfield, J.F. and Murakami, T., (1998) Atomic-resolution transmission electron microscope evidence for the mechanism hy which chlorite weathers to 1:1 semi-regular chloritevermiculite American Mineralogist 83 348357 10.2138/am-1998-3-419.CrossRefGoogle Scholar
Bauluz, B. Peacor, D.R. and Gonzalez Lopez, J.M., (2000) Transmission electron microscopy study of illitization in pelites from the Iherian Range, Spain: layer-hy-layer replacement? Clays and Clay Minerals 48 374384 10.1346/CCMN.2000.0480308.CrossRefGoogle Scholar
Bauluz, B. Peacor, D.R. and Ylagan, R.F., (2002) Transmission electron microscopy study of smectite illitization during hydrothermal alteration of a rhyolitic hyaloclastite from Ponza, Italy Clays and Clay Minerals 50 157173 10.1346/000986002760832766.CrossRefGoogle Scholar
Bell, T.E., (1986) Microstructure in mixed-layer illite/smectite and its relationship to the reaction of smectite to illite Clays and Clay Minerals 34 146154 10.1346/CCMN.1986.0340205.CrossRefGoogle Scholar
Buseck, P.R. and Buseck, P.R., (1992) Imaging and diffraction Minerals and Reactions at the Atomic Scale: TEM Washington, D.C. Mineralogical Society of America 136 10.1515/9781501509735.CrossRefGoogle Scholar
Dong, H. Peacor, D.R. and Freed, R.L., (1997) Phase relations among smectite, R1 illite-smectite, and illite American Mineralogist 82 379391 10.2138/am-1997-3-416.CrossRefGoogle Scholar
Drits, V.A., (1987) Mixed-layer minerals: diffraction methods and structural features Proceedings of the International Clay Conference, Denver 3345.Google Scholar
Guthrie, G.D. Jr. and Vehlen, D.R., (1989) High-resolution transmission electron microscopy of mixed-layer illite/smectite: Computer simulations Clays and Clay Minerals 37 111 10.1346/CCMN.1989.0370101.CrossRefGoogle Scholar
Guthrie, G.D. Jr. and Vehlen, D.R., (1990) Interpreting onedimensional high-resolution transmission electron micrographs of sheet silicates hy computer simulation American Mineralogist 75 276288.Google Scholar
Inoue, A. Velde, B. Meunier, A. and Touchard, G., (1988) Mechanism of illite formation during smectite-to-illite conversion in a hydrothermal system American Mineralogist 73 13251334.Google Scholar
Inoue, A. Meunier, A. and Beaufort, D., (2004) Illite-smectite mixed-layer minerals in felsic volcaniclastic rocks from drill cores, Kakkonda, Japan Clays and Clay Minerals 52 6684 10.1346/CCMN.2004.0520108.CrossRefGoogle Scholar
Inoue, A. Lanson, B. Fernandes, M.M. Sakharov, B.A. Murakami, T. Meunier, A. and Beaufort, D., (2005) Illite-smectite mixed-layer minerals in hydrothermal alteration of volcanic rocks: I. One-dimensional XRD structure analysis and characterization of component layers Clays and Clay Minerals 53 423439 10.1346/CCMN.2005.0530501.CrossRefGoogle Scholar
Kilaas, R., (1998) Optical and near-optical filters in highresolution electron microscopy Journal of Microscopy 190 4551 10.1046/j.1365-2818.1998.3070861.x.CrossRefGoogle Scholar
Kim, J.-W. Peacor, D.R. Tessier, D. and Elsass, F., (1995) A technique for maintaining texture and permanent expansion of smectite interlayers for TEM observations Clays and Clay Minerals 43 5157 10.1346/CCMN.1995.0430106.CrossRefGoogle Scholar
Krekeler, M.P.S. Guggenheim, S. and Rakovan, J., (2004) A microtexture study of palygorskite-rich sediments from the Hawthorne Formation, southern Georgia, hy transmission electron microscopy and atomic force microscopy Clays and Clay Minerals 52 263274 10.1346/CCMN.2004.0520302.CrossRefGoogle Scholar
Kogure, T. and Banfield, J.F., (2000) New insights into the hiotite chloritization mechanism via polytype analysis American Mineralogist 85 12021208 10.2138/am-2000-8-913.CrossRefGoogle Scholar
Murakami, T. Sato, T. and Watanahe, T., (1993) Microstructure of interstratified illite/smectite at 123 K: A new method for HRTEM examination American Mineralogist 78 465468.Google Scholar
Richardson, S.M. Richardson, J.W. Jr., (1982) Crystal structure of a pink muscovite from Archer’s Post, Kenya: Implications for reverse pleochroism in dioctahedral micas American Mineralogist 67 6975.Google Scholar
Stixrude, L. and Peacor, D.R., (2002) First-principles study of illite-smectite and implications for clay mineral systems Nature 420 165168 10.1038/nature01155.CrossRefGoogle ScholarPubMed
Stucki, J.W. and Tessier, D., (1991) Effects of iron oxidation state on the texture and structural order of Na-nontronite gels Clays and Clay Minerals 39 137143 10.1346/CCMN.1991.0390204.CrossRefGoogle Scholar
Tillick, D.A. Peacor, D.R. and Mauk, J.L., (2001) Genesis of dioctahedral phyllosilicates during hydrothermal alteration of volcanic rocks: I. The Golden Cross epithermal deposit, New Zealand Clays and Clay Minerals 49 126140 10.1346/CCMN.2001.0490203.CrossRefGoogle Scholar
Vali, H. and Hesse, R., (1990) Alkylammonium ion treatment of clay minerals in ultrathin section: A new method for HRTEM examination of expandable layers American Mineralogist 75 14431446.Google Scholar
Vali, H. and Koster, H.M., (1986) Expanding behaviour, structural disorder, regular and random irregular interstratification of 2:1 layer-silicates studied hy high-resolution images of transmission electron microscopy Clay Minerals 21 827859 10.1180/claymin.1986.021.5.01.CrossRefGoogle Scholar
Yan, Y. Tillick, D.A. Peacor, D.R. and Simmons, S.F., (2001) Genesis of dioctahedral phyllosilicates during hydrothermal alteration of volcanic rocks: II. The Broadlands-Ohaaki hydrothermal system, New Zealand Clays and Clay Minerals 49 141155 10.1346/CCMN.2001.0490204.CrossRefGoogle Scholar