Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-10T07:17:11.918Z Has data issue: false hasContentIssue false
  • English
  • Français

Tem and X-Ray Diffraction Evidence for Cristobalite and Tridymite Stacking Sequences in Opal

Published online by Cambridge University Press:  28 February 2024

Jessica M. Elzea  and
Stephen B. Rice
Jessica M. Elzea
Affiliation:
Thiele Kaolin Company, P.O. Box 1056, Sandersville, GA 31082
Stephen B. Rice
Affiliation:
McCrone Associates, 850 Pasquinelli Drive, Westmont, IL 60559
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.

In an attempt to resolve the structure of opal-CT and opal-C more precisely, 24 opal samples from bentonites, Fuller's Earths, zeolite tuffs, biogenic silicas and silicified kaolins have been analyzed by high resolution transmission electron microscopy (HRTEM) and X-ray diffraction (XRD). Results of this examination demonstrate that opal-C and opal-CT are part of a continuous series of intergrowths between end-member cristobalite and tridymite stacking sequences.

These findings are consistent with Flörke's (1955) interpretation of the most intense opal peak at ~4 Å as a combination of the (101) cristobalite and (404) tridymite peaks. The position and width of this peak are controlled by the relative volume of the two stacking types and the mean crystallite size. Direct evidence obtained by HRTEM provides data showing various stacking sequences in opals. Broadening due to crystallite size alone was determined by directly measuring crystallite size by TEM and comparing the measured size to the apparent size calculated using the Scherrer equation. XRD peak broadening is also described in terms of various contributions from structural disorder. The mean opal crystallite size ranges from 120 to 320 Å. For samples at either end of the size range, the crystallite size plays a larger role, relative to stacking disorder, in controlling peak broadening.

Keywords

OpalTransmission Electron MicroscopyX-Ray Diffraction
Type
Research Article
Information
Clays and Clay Minerals , Volume 44 , Issue 4 , August 1996 , pp. 492 - 500
Copyright
Copyright © 1996, The Clay Minerals Society

References

Adams, S.J., Hawkes, G.E. and Curzon, E.H.. 1991. A solid state 29Si nuclear magnetic resonance study of opal and other hydrous silicas. Am Miner 76: 18631871.Google Scholar
de Jong, B.H.W., van Hoek, S.J., Veeman, W.S. and Manson, D.V.. 1987. X-ray diffraction and 29Si magic-angle spinning NMR of opals: Incoherent long- and short-range order in opal-CT. Am Miner 72: 11951203.Google Scholar
Elzea, J.M., Odom, I.E. and Miles, W.J.. 1994. Distinguishing well ordered opal-CT and opal-C from high temperature cristobalite by x-ray diffraction. Analytica Chim Acta 286: 107116.CrossRefGoogle Scholar
Flörke, O.W.. 1955. Zur frage des “hoch”-cristobalit in opalen, bentoniten und gläsern. Neues Jahrbuch für Mineralogie Monatshefte 217233.Google Scholar
Frölich, F.. 1989. Deep-sea biogenic silica: new structural and analytical data from infrared analysis—geological implications. Terra Nova 1: 267273.CrossRefGoogle Scholar
Graetsch, H., Mosset, A. and Gies, H.. 1990. XRD and 29Si MAS-NMR study on some non-crystalline silica minerals. J Non-crystal Sol 119: 173180.CrossRefGoogle Scholar
Guthrie, G.O. Jr., Bish, D.L. and Reynolds, R.C. Jr. 1995. Modeling the X-ray diffraction patterns of opal. Am Miner 80: 869872.CrossRefGoogle Scholar
Jones, J.B., Sanders, J.V. and Segnit, E.R.. 1964. Structure of opal. Nature 204: 990991.CrossRefGoogle Scholar
Jones, J.B. and Segnit, E.R.. 1971. The nature of opal I. Nomenclature and constituent phases. J Geol Soc Aust 18: 5768.CrossRefGoogle Scholar
Langer, K. and Flörke, O.W.. 1974. Near infrared absorption spectra (4000-9000 cm–1) of opals and the role of “water” in these SiO2nH2O minerals. Fortschrift der Miner 52: 1751.Google Scholar
Li, D., Bancroft, G.M., Kasrai, M., Fleet, M.E., Secco, R.A., Feng, X.H., Tan, K.H. and Yang, B.X.. 1994. X-ray absorption spectroscopy of silicon dioxide (SiO2) polymorphs: The structural characterization of opal. Am Miner 79: 622632.Google Scholar
Rice, S.B., Freund, H., Clouse, J.A., Fleissner, T.G. and Isaacs, C.M.. 1995. Application of Fourier transform infrared spectroscopy to silica diagenesis: the opal-A to opal-CT transformation, A. Sedimentary Processes. J Sedimen Res A65: 639647.Google Scholar
Wilson, M.J., Russell, J.D. and Tate, J.M.. 1974. A new interpretation of the structure of disordered α-cristobalite. Contributions to Mineral & Petrol 47: 16.CrossRefGoogle Scholar