Hostname: page-component-7dd5485656-bvgqh Total loading time: 0 Render date: 2025-10-31T01:58:15.180Z Has data issue: false hasContentIssue false
  • English
  • Français

The Composition of Kaolinite—an Electron Microscope Microprobe Study

Published online by Cambridge University Press:  01 July 2024

W. B. Jepson  and
J. B. Rowse
W. B. Jepson
Affiliation:
Central Laboratories, E.C.L.P. & Co. Ltd., St. Austell, Cornwall, UK
J. B. Rowse
Affiliation:
Central Laboratories, E.C.L.P. & Co. Ltd., St. Austell, Cornwall, UK
Get access Rights & Permissions [Opens in a new window]

Abstract

Electron microscope microprobe analysis (EMMA) has been applied to the determination of the elemental compositions of the kaolinite particles (Mg, Al, Si, K, Ti and Fe) contained in the 0·2-0·3 µm e.s.d., the 0·9-1·0 µm e.s.d. and the 1·9-2·0 µm e.s.d. fractions of an English kaolin and an American kaolin. Particles with masses as small as 10-13 g were analysed. An EMMA-4 instrument (A.E.I. Ltd.) equipped with linear fully focussing spectrometers was used. The ratio method of analysis was employed. The operating procedures used to obtain the required high experimental precision in the measurement of Al:Si atom ratio are discussed.

Statistical analysis of the results gives the estimated mean and spread of the Al:Si atom ratios. In the English kaolin the mean Al:Si atom ratio differs from the ideal 1:1 at the 0·05 significance level. There is evidence for a variation in composition from kaolinite particle to kaolinite particle in the 1·9-2·0 µm fraction of each kaolin. In the 0·9-1·0 µm fractions, the mean Fe:Si atom ratio was close to 0·002 showing the presence of iron in the kaolinite structure. The mean K:Si ratio was about 0·002 which would be equivalent to 1 unit muscovite layer associated with a 0·175 µm thick kaolinite particle. In the American clay the Ti:Si atom ratio was 0·002 suggesting that some 12 per cent of the 'titania' found by conventional chemical analysis was associated with the kaolinite particles either as titania itself or as an isomorphous substituent.

Information

Type
Research Article
Information
Clays and Clay Minerals , Volume 23 , Issue 4 , August 1975 , pp. 310 - 317
Copyright
Copyright © 1975, The Clay Minerals Society

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Article purchase

Temporarily unavailable

References

Angel, B. R. and Hall, P. L., (1972) Electron spin resonance studies of kaolins Int. Clay Conf. 7186.Google Scholar
Bidwell, J. I. Jepson, W. B. and Toms, G. L., (1970) The interaction of kaolinite with polyphosphate and polyac-rylate in aqueous solutions—some preliminary results Clay Minerals 8 445.CrossRefGoogle Scholar
Chatfield, C., (1970) Statistics for Technology Middlesex, U.K Penguin Books, Harmondsworth.Google Scholar
Dolcater, D. L. Syers, J. K. and Jackson, M. L., (1970) Titanium as free oxide and substituted forms in kaolinites and other soil minerals Clays and Clay Minerals 18 7179.CrossRefGoogle Scholar
Hall, T. A. and G, O., (1971) The microprobe assay of chemical elements Physical Techniques in Biological Research New York Academic Press 157275.Google Scholar
Hodson, S. and Marshall, J., (1971) Migration of potassium out of electron microscope specimens J. Microscopy 93 4953.CrossRefGoogle ScholarPubMed
Jenkins, J. and De Vries, J. L., (1967) Practical X-ray Spectrometry London MacMillan.Google Scholar
Jones, R. C. and Uehara, G., (1973) Amorphous coatings on mineral surfaces Soil Sci. Soc. Am. Proc. 37 792798.CrossRefGoogle Scholar
Lorimer, G. W. and Champness, P. E., (1973) Combined electron microscopy and analysis of an orthopyroxene Am. Miner. 58 243248.Google Scholar
Mackenzie, R. C., (1950) A micro method for determination of cation-exchange capacity of clay Clay Minerals Bull. 1 203205.10.1180/claymin.1952.001.7.03CrossRefGoogle Scholar
Maiden, P. J. and Meads, R. E., (1967) Substitution by iron in kaolinite Nature, Lond. 5103 844846.Google Scholar
Maiden, P. J. and Meads, R. E., (1975) Electron spin resonance in natural kaolinites containing Fe3+ and other transition metal ions .Google Scholar
Mitchell, B. D. and Mackenzie, R. C., (1954) Removal of free iron oxide from clays Soil Sci. 77 173184.CrossRefGoogle Scholar
Nissen, H. U. Champness, P. E. Cliff, G. and Lorimer, G. W., (1973) Chemical evidence for exsolution in a labradorite Nature Phys. Sci. 245 135137.CrossRefGoogle Scholar
Range, K.-J. Range, A. and Weiss, A., (1969) Fire-clay type kaolinite or fire-clay mineral? Experimental classification of kaolinite-halloysite minerals Int. Clay Conf. 1 313.Google Scholar
Rowse, J. B. Jepson, W. B. Bailey, A. T. Climpson, N. A. and Soper, P. M., (1974) Composite elemental standards for quantitative electron microscope microprobe analysis J. Phys. E: Sci. Inst. 7 512514.10.1088/0022-3735/7/7/005CrossRefGoogle Scholar
Weaver, C. E. and Pollard, L. D., (1973) Developments in Sedimentology-15: The Chemistry of Clay Minerals New York Elsevier.Google Scholar
Weiss, A. and Range, K.-J., (1966) On titanium in the kaolinite lattice Int. Clay Conf 1 5366.Google Scholar