Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-28T21:19:57.144Z Has data issue: false hasContentIssue false

Low-Temperature Synthesis of Micas under Conventional- and Microwave-Hydrothermal Conditions

Published online by Cambridge University Press:  01 January 2024

Sridhar Komarneni*
Affiliation:
Department of Crop and Soil Sciences, Materials Research Laboratory, The Pennsylvania State University, University Park, PA 16802, USA
Bharat L. Newalkar*
Affiliation:
Department of Crop and Soil Sciences, Materials Research Laboratory, The Pennsylvania State University, University Park, PA 16802, USA
*
*E-mail address of corresponding author: komarneni@psu.edu
Current address: Corporate R&D Centre, Bharat Petroleum Corporation Limited, Plot 2A, Udyog Kendra, Greater Noida-201306, India
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Several micas containing different octahedral and interlayer cations were synthesized at different temperatures under conventional- and microwave-hydrothermal conditions and these phases were characterized by powder X-ray diffraction, solid-state magic angle spinning nuclear magnetic resonance (MAS-NMR) spectroscopy, scanning electron microscopy and Fourier transform infrared spectroscopy. A Zn K-mica with Zn in the octahedral sheets and K in the interlayers was synthesized in the temperature range 150–200°C and a novel Zn Rb-mica with Zn in the octahedral sheets and Rb in the interlayers was synthesized at 200°C. The synthesis of either Mg, Co or Ni K-micas, however, was found to be difficult or impossible at these low temperatures. Solid-state 29Si MAS-NMR revealed that the Al in the tetrahedral sites is disordered with several nearest-neighbor Si environments. In general, microwave-assisted hydrothermal conditions led to better crystallization of the Zn K-micas compared with the conventional method.

Type
Research Article
Copyright
Copyright © 2003, The Clay Minerals Society

References

Baghurst, D.R. and Mingos, D.M.P. (1992) Superheating effects associated with microwave dielectric heating. Journal of Chemical Society, Chemical Communications, 674677.Google Scholar
Beall, G.H. (1972) Mica glass-ceramics. United States Patent 3,689,293.Google Scholar
Beall, G.H., Grossman, D.G., Hoda, S.N. and Kubinski, K.R. (1980) Inorganic gels and ceramic papers, films, fibers, boards, and coatings made therefrom. United States Patent 4,239,519.Google Scholar
Beall, G.H., Doman, R.C. and Pinckney, L.R. (1986) Sodium fluoromica glass-ceramics. United States Patent 4,624,933.Google Scholar
Comeforo, J.E. Hatch, R.A. Humphrey, R.A. and Eitel, W., (1953) Synthetic mica investigations: I. A hot-pressed machinable ceramic dielectric Journal of American Ceramic Society 36 286294 10.1111/j.1151-2916.1953.tb12884.x.Google Scholar
Comodi, P. Zanazzi, P.F. Weiss, Z. Rieder, M. and Drabek, M., (1999) Cs-tetra-ferri-annite: High-pressure and high-temperature behavior of a potential nuclear waste disposal phase American Mineralogist 84 325332 10.2138/am-1999-0315.Google Scholar
Daimon, N. and Izawa, T. (1976) Sol of ultra-fine particles of synthetic hectorite. United States Patent 3,936,383.Google Scholar
Daimon, N. and Kitajima, K. (1978) Synthetic tetrasilicic mica and water sol thereof. United States Patent 4,067,819.Google Scholar
Eitel, W. Hatch, R.A. and Denny, M.V., (1953) Synthetic mica investigations: II. Role of fluorides in mica batch reactions Journal of American Ceramic Society 36 341348 10.1111/j.1151-2916.1953.tb12814.x.Google Scholar
Eppler, R.A. (1961) Method of making crystalline mica bodies and products. United States Patent 3,149,982.Google Scholar
Frondel, C. and Ito, J., (1966) Hendricksite, a new species of mica American Mineralogist 51 11071123.Google Scholar
Gregorkiewitz, M., (1972) Zur Darstellung von Tektosilicates in Salzen-Schemelzen Germany Diplomarbeit, Universität München.Google Scholar
Gregorkiewitz, M. and Rausell-Colom, J.A., (1987) Characterization and properties of a new synthetic silicate with highly charged mica-type layers American Mineralogist 72 515527.Google Scholar
Grossman, D.G. (1974) Tetrasilicic mica glass ceramic article. United States Patent 3,839,055.Google Scholar
Hatch, R.A. (1961) Synthetic mica flakes and structures. United States Patent 3,001,571.Google Scholar
Hazen, R.M. and Wones, D.R., (1972) The effect of cation substitutions on the physical properties of trioctahedral micas American Mineralogist 57 103129.Google Scholar
Hessinger, P.S., Caldwell, W. and Weber, T. (1965) Method of making synthetic mica and ceramoplastic materials. United States Patent 3,197,279.Google Scholar
Higashi, S. Miki, K. and Komarneni, S., (2002) Hydrothermal synthesis of Zn-smectites Clays and Clay Minerals 50 299305 10.1346/00098600260358058.Google Scholar
Klingsberg, C. and Roy, R., (1957) Synthesis, stability and polytypism of nickel, and gallium phlogopite American Mineralogist 42 629634.Google Scholar
Komarneni, S. and Roy, R., (1986) Topotactic route to synthesis of novel hydroxylated phases. I. Trioctahedral micas Clay Minerals 21 125131 10.1180/claymin.1986.021.2.02.Google Scholar
Komarneni, S. and White, W.B., (1981) Hydrothermal reactions of clay minerals and shales with cesium phases from spent fuel elements Clays and Clay Minerals 29 299308 10.1346/CCMN.1981.0290408.Google Scholar
Komarneni, S. Fyfe, C.A. Kennedy, G.J. and Strobl, H., (1986) Characterization of synthetic and naturally occurring clays by 27Al and 29Si magic-angle spinning NMR spectroscopy Journal of American Ceramic Society 69 C45–C-47.Google Scholar
Komarneni, S. Roy, R. and Li, Q.H., (1992) Microwavehydrothermal synthesis of ceramic powders Materials Research Bulletin 27 13931405 10.1016/0025-5408(92)90004-J.Google Scholar
Komarneni, S. Pidugu, R. and Amonette, J.E., (1998) Synthesis of Na-4-mica from metakaolinite and MgO: Characterization and Sr2+ uptake kinetics Journal of Materials Chemistry 8 205208 10.1039/a706050e.Google Scholar
Komarneni, S. Pidugu, R. Hoffbauer, W. and Schneider, H., (1999) A synthetic Na-rich mica: Synthesis and characterization by 27Al and 29Si magic angle spinning nuclear magnetic resonance spectroscopy Clays and Clay Minerals 4 410416 10.1346/CCMN.1999.0470403.Google Scholar
Neas, E.D. Collins, M.J., Kingston, H.M. and Jassie, L.B., (1988) Microwave heating: Theoretical concepts and equipment design Introduction to Microwave Sample Preparation, Theory and Practice Washington, D.C. American Chemical Society 732.Google Scholar
Paulus, W.J. Komarneni, S. and Roy, R., (1992) Bulk synthesis and selective exchange of strontium ions in Na4Mg6Al4Si4O20F4 mica Nature 357 571573 10.1038/357571a0.Google Scholar
Perrotta, A.J. and Garland, T.J., (1975) Low temperature synthesis of zinc phlogopite American Mineralogist 60 152154.Google Scholar
Redhammer, G.J. Beron, A. Schneider, J. Amthauer, G. and Lottermoser, W., (2000) Spectroscopic and structural properties of synthetic micas on the annite-siderophyllite binary: synthesis, crystal structure refinement, Mössbauer, and infrared spectroscopy American Mineralogist 85 449465 10.2138/am-2000-0406.Google Scholar
Sanz, J. and Serratosa, M., (1984) 29Si and 2 Al high-resolution MAS-NMR spectra of phyllosilicates Journal of American Chemical Society 106 47904793 10.1021/ja00329a024.Google Scholar
Yoder, H.S. and Eugster, H.P., (1955) Synthetic and natural muscovites Geochimica et Cosmochimica Acta 8 225280 10.1016/0016-7037(55)90001-6.Google Scholar