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X-Ray Study of Interactions between Montmorillonite Platelets

Published online by Cambridge University Press:  01 July 2024

Donald E. Andrews ,
Paul W. Schmidt  and
H. van Olphen
Donald E. Andrews
Affiliation:
Physics Dept., University of Missouri, Columbia, Mo.
Paul W. Schmidt
Affiliation:
Physics Dept., University of Missouri, Columbia, Mo.
H. van Olphen*
Affiliation:
Shell Development Company (A Division of Shell Oil Company), Exploration and Production Division, Box 481, Houston, Texas
*
Present address: Office of Critical Tables, National Research Council, 2101 Constitution Ave., NW, Washington, D.C. 20418.
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Abstract

Small angle X-ray scattering curves have been obtained for a series of Na Wyoming Bentonite clay samples containing 10% clay by weight and NaPO3 in concentrations ranging from 0 to 100 meq/1. From the scattering data, the relative probability of spacings between parallel clay platelets was computed. For the sample containing no NaPO3, the probability distribution showed a relatively broad maximum at an interparticle spacing of about 180Å. As the concentration of NaPO3 increased, the maximum became sharper and occurred for smaller interparticle distances. At NaPO3 concentrations between 25 and 100 meq/1, the position d of the maximum was given approximately by the equation d = 21 + 18.4c-1/2, where d is in angstroms, and c is the NaPOs concentration in eq/1. The similarity of this relation to the dependence of d on the concentration of NaCl (Norrish and Rausell-Colom, 1963; Norrish, 1954) suggests that the interparticle spacing depends primarily on the sodium ion concentration and not on the concentration of the anion. The value of d appears to be independent of whether the gel was prepared by the method of Norrish and Rausell-Colom, in which a dried flake was allowed to come to equilibrium with an electrolyte solution, or whether, as in this investigation, the gel was obtained by centrifuging a dilute suspension. Since the Na ions act to reduce the double-layer repulsion between platelets, while the anions tend to be adsorbed on the platelet edges and thus reduce the edge-to-face linkages (H. van Olphen, 1962), the value of the most probable interparticle distance appears to be determined primarily by the magnitude of the double-layer repulsion, even though other properties of the clay gels, such as the rheological behavior, are governed mainly by edge-to-face attractions.

Type
General
Information
Clays and Clay Minerals , Volume 15 , February 1967 , pp. 321 - 330
Copyright
Copyright © 1967, Springer International Publishing

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Footnotes

*

Work supported by Shell Development Co. and by the National Science Foundation.

References

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