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Kinetic Studies on Montmorillonites and Nontronite by the Acid-Dissolution Technique

Published online by Cambridge University Press:  01 January 2024

Bernard Osthaus*
Affiliation:
Gulf Research & Development Company, Pittsburgh, Pennsylvania, USA
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Abstract

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Several montniorillonites and a nontronite were digested in hydrochloric acid at constant temperature for various periods of time. Soluble iron, aluminum, magnesium, and in two samples titanium, were determined for each digestion period. Rate of solution curves were obtained by plotting the logarithm of the percent of the residual ions against time. In general, the solution curves were straight lines or curves that could be resolved into two straight lines. From the interpretation of the dissolution curves, it was possible to determine the amount of the ions in octahedral and tetrahedral coordination. For some of the samples, the rate curves also gave the amount of iron and/or aluminum extraneous to the clay lattice. The amount of silicon in the clay lattice was calculated using the experimentally determined octahedral cations, substituted tetrahedral cations if any, and the exchangeable cations assuming 44 charges per unit cell. The distribution of cations in lattice layers indicates that the eight montniorillonites are substantially dioctahedral. Two of the samples showed the presence of iron in tetrahedral coordination while all the samples showed extraneous silicon. The presence of extraneous silicon, iron, and aluminum in purified samples indicates that formulas derived from bulk chemical analyses can be inaccurate.

The dissolution of the ions from the clay lattice determined at several different temperatures in one sample and at two acid concentrations in another sample is in agreement with chemical kinetic principles and is a first-order reaction. The rate constant for the acid dissolution reaction increased proportionately with the acid concentration.

The activation energies were determined for the solution of iron and aluminum in mont-morillonite from Polkville, Mississippi, and nontronite from Garfield, Washington, using Arrhenius’ Law. In both samples the activation energies (17 to 18 kilocalories per mole) were the same. In the nontronite sample the activation energies were identical for what have been interpreted as octahedral and tetrahedral ions.

Type
Article
Copyright
Copyright © The Clay Minerals Society 1955

Footnotes

Publication authorized by Executive Vice-President, Gulf Research & Development Company

References

Brindley, G. W., and Youell, R. F., 1951, A chemical determination of the tetrahedral and octahedral aluminum ions in a silicate: Acta Cryst., v. 4, p. 495497.CrossRefGoogle Scholar
Earley, J. W., Osthaus, B. B., and Milne, I. H., 1953, Purification and properties of montmorillonite: Amer. Min., v. 38, p. 707724.Google Scholar
Foster, M. D., 1953, Geochemical studies of clay minerals: III The determination of free silica and free alumina in montmorillonite s: Geochimica et Gosmochimica Acta, v. 3, p. 143154.Google Scholar
Karsulin, M., and Stubican, Vl., 1954, Über die Struktur und die Eigenschaften synthetisher Montmorillonite: Monatshefte für Chemie, v. 85, p. 343358.CrossRefGoogle Scholar
Kelley, W. P., 1945, Calculating formulas for fine grained minerals on the basis of chemical analysis: Amer. Min., v. 30, p. 126.Google Scholar
Kerr, P. F., and others, 1951, Reference clay minerals: A.P.I. Project 49.Google Scholar
Osthaus, B. B., 1954, Chemical determination of tetrahedral ions in nontronite and montmorillonite: in Clays and clay minerals, Nat. Acad. Sci.—Nat. Res. Council, Pub. 327, p. 404417.Google Scholar
Ross, C. S., and Hendricks, S. B., 1945, Minerals of the montmorillonite group, their origin and relation to soils and clays: U. S. Geol. Survey Prof. Paper 205-B, p. 2379.Google Scholar