FURTHER TITLES IN THIS SERIES VOLUMES 1.2.3,5,8 and 9 are out of print 4 F.G. TICKELL THE TECHNIQUES OF SEDIMENTARY MINERALOGY 6 L. VAN DER PLAS THE IDENTIFICATION OF DETRITAL FELDSPARS I S. DZULYNSKI and E.K. WALTON SEDIMENTARY FEATURES OF FLYSCH AND GREYWACKES 10 P.McL.D. DUFF, A. HALLAM and E.K. WALTON CYCLIC SEDIMENTATION 11 C.C. REEVES Jr. INTRODUCTION TO PALEOLIMNOLOGY 12 R.G.C. BATHURST CARBONATE SEDIMENTS AND THEIR DIAGENESIS 13 A.A. MANTEN SILURIAN REEFS OF GOTLAND 14 K. W. GLENNIE DESERT SEDIMENTARY ENVIRONMENTS 15 C.E. WEAVER and L.D. POLLARD THE CHEMISTRY OF CLAY MINERALS 16 H.H. RIEKE I11 and G.V. CHILINGARIAN COMPACTION OF ARGILLACEOUS SEDIMENTS 11 M.D. PICARD and L.R. HIGH Jr. SEDIMENTARY STRUCTURES OF EPHEMERAL STREAMS 18 G. V. CHILINGARIAN and K.H. WOLF, Editor8 COMPACTION OF COARSE-GRAINED SEDIMENTS 19 W. SCHWARZACHER SEDIMENTATION MODELS AND QUANTITATIVE STRATIGRAPHY 20 M.R. WALTER,E ditor STROMATOLITES 21 B. VELDE CLAYS AND CLAY MINERALS IN NATURAL AND SYNTHETIC SYSTEMS 22 C.E. WEAVERa nd K.C. BECK MIOCENE 0.F THE SOUTHEASTERN UNITED STATES 23 B.C. HEEZEN, Editor INFLUENCE OF ABYSSAL CIRCULATION ON SEDIMENTARY ACCUMULATIONS IN SPACE AND TIME 24 R.E. GRIM and GUVEN BENTONITES 25A G. LARSEN and G.V. CHILINGAR,E ditors DIAGENESIS IN SEDIMENTS AND SEDIMENTARY ROCKS, I 26 T. SUDO and S. SHIMODA, Editors CLAYS AND CLAY MINERALS OF JAPAN 21 M.M. MORTLAND and V.C. FARMER, Editors INTERNATIONAL CLAY CONFERENCE 1978 28 A. NISSENBAUM, Editor HYPERSALINE BRINES AND EVAPORITIC ENVIRONMENTS 29 P. TURNER CONTINENTAL RED BEDS 30 J.R.L. ALLEN SEDIMENTARY STRUCTURES 31 T. SUDO. S. SHIMODA, H. YOTSUMOTO and S. AITA ELECTRON MICROGRAPHS OF CLAY MINERALS 32 C.A. NITTROUER, Editor SEDIMENTARY DYNAMICS OF CONTINENTAL SHELVES 33 G.N. BATURIN PHOSPHORITES ON THE SEA FLOOR 34 J.J. FRIPIAT, Editor ADVANCED TECHNIQUES FOR CLAY MINERAL ANALYSIS 35 H. VAN OLPHEN and F. VENIALE, Editors INTERNATIONAL CLAY CONFERENCE 1981 36 A. IIJIMA, J.R. HEIN and R. SIEVER, Editors SILICEOUS DEPOSITS IN THE PACIFIC REGION 31 A. SINGER and E. GALAN, Editors PALYGORSKITE-SEPIOLITE: OCCURRENCES, GENESIS AND USES 38 M.E. BROOKFIELD and T.5. AHLBRANDT, Editors EOLIAN SEDIMENTS AND PROCESSES 39 B. GREENWOOD and R.A. DAVIS Jr., Editom HYDRODYNAMICS AND SEDIMENTATION IN WAVE-DOMINATED COASTAL ENVIRONMENTS DEVELOPMENTS IN SEDIMENTOLOGY 40 CLAY MIN E RALS A Physico- Chemical Explanati on of their Occurrence B. VELDE Ecole Normale Supgrieure, Laboratoire de Ggologie, 46 Rue d’Ulm, 75230 Paris Cgdex (France) ELSEVIER Amsterdam - Oxford -New York - Tokyo 1985 ELSEVIER SCIENCE PUBLISHERS B.V. 1 Molenwerf P.O. Box 211,1000 AE Amsterdam, The Netherlands Distributors for the United States and Canada: ELSEVIER SCIENCE PUBLISHING COMPANY INC. 52, Vanderbilt Avenue New York, N.Y. 10017 Library of Congress Cataloging in Publication Data Velde, B. Clay minerals. (Developments in sedimentology ; 40) Bibliography: p. Includes index. 1. Clay dnerals. I. Title. 11. Series. w38g.m.v43 1985 5491.6 84-21204 ISBN 0-444-42423-7 (U. S. ) ISBN 0-444-42423-(7V ol. 40) ISBN 0-444-41238-(7S eries) 0 Elsevier Science Publishers B.V., 1985 All rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means, electronic, mechanical, photocopy- ing, recording or otherwise without the prior written permission of the publisher, Elsevier Science Publishers B.V./Science & Technology Division, P.O. Box 330, 1000 AH Amster- dam, The Netherlands. Special regulations for readers in the USA - This publication has been registered with the Copyright Clearance Center Inc. (CCC), Salem, Massachusetts. Information can be ob- tained from the CCC about conditions under which photocopies of parts of this publica- tion may be made in the USA. All other copyright questions, including photocopying outside of the USA, should be referred to the publisher. Printed in The Netherlands V BIBLIOGRAPHICAL DATA Bruce Velde, Directeur de Recherche in the Centre National de la Recherche Scientifique, now works in the Laboratoire de G&ologie, Ecole Normale Supgrieure in Paris. He began his undergraduate work in the University of Illi- nois in 1956 and obtained a PhD from the University of Mon- tana in 1962. He was a fellow at the Carnegie Geophysical Laboratory, Wash. D.C. in' 1962-1964 and 1976. His career in C.N.R.S. began in the Sorbonne, Laboratoire de Pgtrographie in 1965. VII PREFACE This book follows another which must be considered as a first attempt to put some order in the house of clay petrology. Its limited success was encouraging enough to begin again the long process of reviewing the current lite- rature, extracting the pertinent data, summarizing and fi- nally analyzing the information at our disposal. A certain number of the questions posed then can now be answered, yet many others await investigation by clay mineralogists. What- ever the short-comings of this book are, they reflect those of the author and not those of his many helpful colleagues and friends. I would like to express my gratitude to John Hower for his guidance and patience over the years, to Alain Meunier for bravely attempting to make sense of my enthu- siasm, to Jacqueline Beauquin for calmly accepting and cor- recting persistent inconsistency. 1 - I INTRODUCTION The study of clay minerals has made a series of ad- vances which were due to new methods of investigation ; such as X-ray diffractometry, or new ideas concerning their ori- gin and evolution, such as the concept of clay petrology pro- posed by C.E. Weaver (1959) and the concept of clay mineral association proposed by G. Millot (1964). In fact, as has been the case in many other disciplines, progress in under- standing the fundamentals of clay mineralogy has come in un- even steps. The essential work in the 19th and early 20th century was that of discovery, isolation and identification of the minerals. Later work in the mid-twentieth century concerned a definition of the structure of clays and their chemistry which is related to this structure. The Geological Survey in the United States produced a number of fundamental papers which defined the chemistry of clay minerals and the mineralogy of phyllosilicates. The next endeavor was to de- termine the geology of clays-developed by Weaver in the Uni- ted States and Millot in France among others. Meanwhile ex- periments were conducted, mainly in France and the United States which attempted to quantify the chemistry of clay mi- neral genesis by experiment or calculation. These two themes have continued sporadically until the present. In 1977, I attempted to summarize the available data, interpret and sort out the major evident "truths" and then propose a se- ries of geochemical and petrographic systems which might explain why many clay assemblages are found commonly in na- ture. Since that time, the electron microprobe has come on the scene. This tool permits one to determine, in favorable circumstances, the spacial and chemical factors which result in the genesis of clay minerals. This new information allows one to make a further stride in the science of clay minera- logy. However, the era of electron microprobe studies is just beginning which means that we have much more to learn in the immediate future. The new information, and that resulting from subse- quent more "classical" studies , has changed the ideas which I had developed in certain cases but in a general way they 2 have served to amplify and extend the domains of investiga- tion which can now be analyzed. For example, we can now look at the problems of clay mineral genesis during weathering in a mineralogical and chemical way which was previously impossible. The same is true for hydrothermal alteration as well as sandstone diagenesis. A new field of endeavor has occurred recently, that of the deep-sea alteration of basalts, which allows one to consider the major chemical transfers which influence the composition of the upper oceanic crust as well as that of the sea. These new fields of investigation will be covered in this book using the "old methods" which were applied to the previously available data for clays in sedimentary and sedimentary rock environments. What then are these old methods ? First, it is consi- dered necessary to determine which clay phases are commonly present and which phases have been sufficiently studied to give an idea of their chemical composition limits. These limits are defined according to the results published in the literature. Most data used appeared between 1950 and 1982. These studies are based upon pure mineral samples which were analyzed by classical methods and which could be identified by X-ray diffraction methods. These are "well characterized" minerals. Microprobe data are compared to these data because, in most instances, X-ray diffraction information is not available for the exact mineral analyzed. Also, classical analysis methods allow one to distinguish Fe2+ from Fe3+, a very important measurement as we will see. One must stop here a moment to consider the processes that are involved in a mineral analysis. Most important, when one makes a classical determination either for X-ray or chemical analysis, a large amount of material is necessary, several hundreds of milligrams, which almost by definition involves material of several different compositions. The mi- croprobe has shown us this. Thus classical analyses are fre- quently average values for mineral mixtures. However, avera- ges are only useful as long as they are considered as such. The author feels, that adequate X-ray data are absolutely necessary to assure that one knows which mineral species is present. Thus microprobe data must be compared, in most cases, to data gathered by other means. Once the types of chemical substitutions are determined for a mineral species, it is possible to extend the limits of our knowledge with electron microprobe data. 3 The next step is to determine the mineral associa- tions of the different clay minerals. This is the method of facies used in metamorphic petrology with such great suc- cess. Which minerals occur together and where ? Using these generalizations one can attempt to construct a chemiographic framework for clay petrology. The major problem with such an approach 1s the possible metastable persistence of a phase or its crystallization outside of its stability field. These problems occur in metamorphic petrology and even more fre- quently in igneous petrology but the practitioners of these arts have not yet been severly hampered by them. There is no reason why clay mineralogists should be. However, we will use possibly more caution in our pronouncements since we know that kinetic problems are great at lower temperatures (which are relative anyway) and that the domains of clay mineral stability are notably difficult to determine at low temperatures, at least as far as geological conditions are concerned. The phase diagrams established in this way will be useful to interpret clay mineral assemblages found in nature with regard to their geological significance. Certain short- comings will be pointed out (others will undoubtedly remain and will be pointed out by the interested reader). The object of this book then is to propose a method for considering the geology of clay minerals which will be modified and perfected as time goes on. Science means re- interpretation of the past. One can never expect to formulate eternal truths in all their detail - at least not in the natural sciences during the latter part of the twentieth century. What then will be used here for the foundations of the analysis ? 4 1 - Choice of Information The information which is used to construct this petrologic interpretation of clay mineral assemblages is essentially of three types : chemical analyses of natural minerals, assemblages of minerals reported in the literature and experimental determinations of clay mineral stabilities. In using data from the literature one is forced to select from the mass available, that which seems most accurate and that which is most directly applicable to a given problem. Inherent in such a process is the problem of personal bias and unintentional oversight. It is certain that pertinent studies have been omitted from the compilation presented here, but it is hoped that these omissions do not prevent an understanding of the petrology of clay minerals. Basically only studies posterior to 1950 have been considered, because information before this time could not be correctly characterized due to relatively poor X-ray diffraction techniques. The main criterion for using studies reporting natural mineral compositions is the quality of X-ray dif- fraction data permitting the verification of the presence of single phase or multiphase samples. Low angles of 2 8 are especially critical where the detection of highly expandable phases is concerned. Thus certain chemical analyses have been arbitrarily eliminated for lack of assurance that a given sample is monomineralic. Nonetheless this problem can- not be discounted even in the analyses selected. Each chemical analysis thus chosen has been calcu- lated into a chemical structural formula using a computer program. The method of calculation is that used by Foster (1953 ; 1962) where a given number of oxygens and hydroxyls is assumed to be present ; Olo(OH)2 for a 2:l structure, Ol0 (OH)8 for a 2:2 chlorite type structure and 05(OH)4 for a 1:l structure. The following site occupancies disqualified an analysis from use : > 3.05 octahedral ions, > 4.05 sili- con and > 1.10 interlayer ions for non-chlorite structures. Calcium contents above 0.20 ion in low temperature micas and in chlorites were considered to be excessive. Trioctahedral, low-alkali phases are considered in the vermiculite-corren- 5 site group. The possibility of significant secondary iron oxidation in numerous samples is considered to be small and in any event inconsequential to the general trend of mineral compositions, thus water contents were not calculated into the structural formulas. The experimental studies have been chosen mainly for the completeness of reported experimental conditions and for their apparent approach to an equilibrium assemblage. These criteria are difficult to adhere to in that experimen- tal data are not abundant and frequently one must make do with what is available in order to gain an understanding of a given problem. However, where several studies overlap, that with the longest experimental durations or reversal equilibria is chosen by preference. Nevertheless a certain amount of caution is necessary to interpret the available experimental results.