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Clay-organic complexes

Published online by Cambridge University Press:  01 July 2024

G. W. Brindley
Affiliation:
Materials Research Laboratory, and Department of Geosciences, The Pennsylvania State University, University Park, Pa. 16802, U.S.A.
Eiji Suito
Affiliation:
Institute of Chemical Research Kyoto University, Uji, Kyoto-fu 611, Japan
M. Koizumi
Affiliation:
Institute of Scientific and Industrial Research Yamadakami, Suita, Osaka 565, Japan
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Abstract

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Type
Notes
Copyright
Copyright © 1972, The Clay Minerals Society

References

Papers presented included:

Clay-organic studies in the U.S.A.—A review. Brindley, G. W..Google Scholar
Clay-organic studies in Japan—A review. Suito, E..Google Scholar
Reactions between clays and organic compounds. Mortland, M. M..Google Scholar
Imogolite —organic interactions. Wada, K., Inoue, T., and Henmi, T..Google Scholar
Reaction of montmorillonite with acrylonitrile. Yamanaka, S., Kanaman, F. and Koizumi, M..Google Scholar
Surface activity and adsorption on kaolinde. Conley, R. F..Google Scholar
Trimethylsilation of calcium silicates. Shiihara, I., Komatsu, K. and Toyama, I..Google Scholar
Physico-chemical methods. Olphan, H. van.Google Scholar
Structural study of clay-organic complexes. Brindley, G. W..Google Scholar
Single crystal study of clay-organic complexes. Kanaman, F., Yamanaka, S. and Koizumi, M..Google Scholar
Interstratified structure of organo-montmorillonites revealed by electron microscopy. Suito, E. and Yoshida, T..Google Scholar
Oriented adsorption of organic molecules as epitaxial nuclei. Uyeda, N., Ashida, M., Yamamoto, K., Kobayashi, T. and Suito, E..Google Scholar
General aspects of the diffraction approaches to the problems. Nakahira, M..Google Scholar
Structure of alkyl-ammonium layer silicate complexes. Johns, W. D..Google Scholar
Kink formation in alkyl chains in montmorillonite. Weiss, A..Google Scholar
Thermal methods and techniques. Slabaugh, W. H..Google Scholar
Application of electron-probe microanalyser to clay studies. Flayami, R..Google Scholar
Cellular processes at work in sediments. Degens, E. T..Google Scholar
Role of clay mineral catalysis in genesis of petroleum hydrocarbons. Johns, W. D..Google Scholar
Explosiveness of benzoylperoxide mixed with bentonite. Yamamoto, D..Google Scholar
Surface and colloidal properties of clay-organic complexes. Olphen, H. van.Google Scholar
Relations between surface modifying and surface properties of some kaolin minerals. Takahashi, H. and Tsutsumi, K..Google Scholar
Spectroscopic methods in the study of clay-organic complexes. Mortland, M. M..Google Scholar
Applications of clay-organic complexes. Olphen, H. van.Google Scholar
Industrial applications of clay-organic complexes. Kato, C..Google Scholar
Reinforcement of rubber with hard clay. Arakawa, M. and Suito, E..Google Scholar
Applications of clay-organic complexes. Slabaugh, W. H..Google Scholar
Rheological applications of organophilic montmorillonites. Hasegawa, H. and Kondo, M..Google Scholar
Organophilic properties of synthetic trioctahedral montmorillonite-organic complexes. Kondo, M. and Okamoto, Y..Google Scholar
Grinding of intercalated dickite and kaolinde. Okuda, S. and Inoue, K..Google Scholar
The use of a differential refractometer. Brindley, G. W..Google Scholar
Summary of the seminar. Brindley, G. W..Google Scholar