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The physical dimensions of fundamental clay particles

Published online by Cambridge University Press:  09 July 2018

P. H. Nadeau
P. H. Nadeau*
Affiliation:
Dept. of Mineral Soils, The Macaulay Institute for Soil Research, Aberdeen, Scotland AB9 2QJ
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Abstract

The thickness, length, width, area and perimeter of 575 particles from 16 aqueously dispersed samples of a variety of interstratified clays, smectites and illite have been recorded using TEM techniques. Complete dispersion of the clay material was achieved by saturating the clay with either Na+ or Li+, removal of excess ions by dialysis, and isolation of the <0·1 or <0·2 µm fraction by centrifugation. The samples have mean maximum dimensions of 1900 to 90 nm and the dispersed system can be considered as colloidal in nature. The mean thickness of the clays is about 1 nm for smectites, corresponding to that of elementary 2:1 silicate layers, from 1·9 to 4·9 nm for the interstratified clays, and 9 nm for illite. From these data the volume, total surface area and other parameters have been calculated and compared with independent determinations of surface area and CEC. The total surface area by TEM, assuming a density of 2·6 g/cm3, varies from ∼675 m2/g for smectites to 86 m2/g for illite, and is inversely proportional to the mean particle thickness. The charge density of monovalent cation exchange sites on the surface of the particles as determined for nine of the samples varies from 0·54 to 1·16 nm2/site. The particle-thickness distribution data can be used to calculate interstratified XRD layer-sequence probabilities and composition parameters, and agree with XRD data for interstratified clay with <60% illite layers. The thickness data also provide a rationale for the interpretation of TEM lattice-fringe images. Relationships between the particle area, length, thickness and volume are shown to be potentially useful in assessing the mechanism(s) of crystal growth of these extremely small phyllosilicate particles.

Type
Research Article
Information
Clay Minerals , Volume 20 , Issue 4 , December 1985 , pp. 499 - 514
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1985

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References

Amouric, M. & Baronnet, A. (1983) Effect of early nucleation conditions on synthetic muscovite polytypism as seen by high resolution transmission electron microscopy. Phys. Chem. Miner. 9, 146159.CrossRefGoogle Scholar
Baronnet, A., Amouric, A. & Chabot, B. (1976) Mécanismes de croissance, polytypisme et polymorphisme de la muscovite hydroxylée synthétique. J. Crystal Growth 32, 3759.Google Scholar
Besson, G., Glaeser, R. & Tchoubar, C. (1983) Le césium, révélateur de structure des smectites. Clay Miner. 18, 1119.Google Scholar
Branson, K. & Newman, A.C.D. (1983) Water sorption on Ca-saturated clays: I. Multilayer sorption and microporosity in some illites. Clay Miner. 18, 277287.Google Scholar
Brindley, G.W. (1980) Order-disorder in clay mineral structures. Pp. 125195 in: Crystal Structures of Clay Minerals and their X-ray Identification (Brindley, G. W. & Brown, G., editors). Mineralogical Society, London.Google Scholar
Brown, G., Newman, A.C.D., Rayner, J.H. & Weir, A.H. (1978) The structures and chemistry of soil clay minerals. Pp. 29178 in: The Chemistry of Soil Constituents (Greenland, D. J. & Hayes, M. H. B., editors). John Wiley and Sons, Chichester.Google Scholar
Conley, R.F. (1966) Statistical distribution of particle size and shape in the Georgia kaolins. Clay Clay Miner. 14, 317330.Google Scholar
Cowking, A., Wilson, M.J., Tait, J.M. & Robertson, R.H.S. (1983) Structure and swelling of fibrous and granular saponitic clays from Orrock Quarry, Fife, Scotland. Clay Miner. 18, 4964.Google Scholar
Greenland, D.J. & Mott, C.J.B. (1978) Surfaces of soil particles. Pp. 321353 in: The Chemistry of Soil Constituents (Greenland, D. J. & Hayes, M. H. B., editors). John Wiley and Sons, Chichester.Google Scholar
Grim, R.E. & Güven, N. (1978) Bentonites (Developments in Sedimentology 24). Elsevier, Amsterdam, 256 PP.Google Scholar
Güven, N. (1974) Lath-shaped units in fine-grained micas and smectites. Clays Clay Miner. 22, 385390.CrossRefGoogle Scholar
Hall, P.L. (1981) Neutron scattering techniques for the study of clay minerals. Pp. 5175 in: Advanced Techniques for Clay Mineral Analysis (Fripiat, J. J., editor). Elsevier, Amsterdam.Google Scholar
Kahn, A. (1963) Studies on the size and shape of clay particles in aqueous suspension. Clays Clay Miner. 6, 220236.Google Scholar
Kodama, H. (1966) The nature of the component layers of rectorite. Am. Miner. 51, 10351055.Google Scholar
Lubetkin, S.D., Middleton, S.R. & Ottewlll, R.H. (1984) Some properties of clay-water dispersions. Pp. 353368 in: Clay Minerals: their Structure, Behaviour and Use (Fowden, L., Barrer, R. M. & Tinker, P. B., editors). Royal Society, London.Google Scholar
MacEwan, D.M.C. & Wilson, M.J. (1980) Interlayer and intercalation complexes of clay minerals. Pp. 197248 in: Crystal Structures of Clay Minerals and their X-ray Identification (Brindley, G. W. & Brown, G., editors). Mineralogical Society, London.CrossRefGoogle Scholar
Mamy, J. & Gaultier, J.P. (1976) Les phénomènes de diffraction des rayonnements X et électronique par le réseaux atomiques. Application à l'études de l'order cristallin dans les mineraux argilleux. II. Evolution structurale de la montmorillonite associée au phénomène de fixation irréversible du potassium. Ann. Agron.27-I, 116.Google Scholar
Marshall, C.E. (1949) The Colloid Chemistry of the Silicate Minerals. Academic Press, New York, 195 pp.Google Scholar
McHardy, M.J., Wilson, M.J. & Tait, J.M. (1982) Electron microscope and X-ray diffraction studies of filamentous illitic clay from sandstones of the Magnus field. Clay Miner. 17, 2339.Google Scholar
Mering, J. & Oberlin, A. (1971) The smectites. Pp. 193229 in: The Eleetron-Optical Investigation of Clays (Gard, J. A., editor). Mineralogical Society, London.Google Scholar
Nadeau, P.H. (1980) Burial and contact metamorphism in the Mancos shale. PhD thesis, Dartmouth College, Hanover, NH, USA.Google Scholar
Nadeau, P.H., Tait, J.M., McHardy, W.J. & Wilson, M.J. (1984a) Interstratified XRD characteristics of physical mixtures of elementary clay particles. Clay Miner. 19, 6776.Google Scholar
Nadeau, P.H., Wilson, M.J., McHardy, W.J. & Tait, J.M. (1984b) Interstratified clays as fundamental particles. Science 225, 923925.Google Scholar
Nadeau, P.H., Wilson, M.J., McHardy, W.J. & Tait, J.M. (1984C) Interparticle diffraction: a new concept for interstratified clays. Clay Miner. 19, 757769.Google Scholar
Nadeau, P.H., Wilson, M.J., McHardy, W.J. & Tait, J.M. (1985) The nature of some illitic clays from bentonites and sandstones: implications for the conversion of smectite to illite during diagenesis. Mineral. Mag. 49, 393400.Google Scholar
Newman, A.C.D. (1983) The specific surface of soils determined by water sorption. J. Soil Sci. 34, 2332.CrossRefGoogle Scholar
Pallatt, N., Wilson, M.J. & McHardy, W.J. (1984) Insights into the relationship between permeability and the morphology of diagenetic illite in reservoir rocks. J. Petroleum Technol. 36, 22252227.Google Scholar
Post, J.L. (1984) Saponite from Ballarat, California. Clays Clay Miner. 32, 147153.Google Scholar
Reynolds, R.C. (1980) Interstratified clay minerals. Pp. 249303 in: Crystal Structures of Clay Minerals and their X-ray Identification (Brindley, G. W. & Brown, G., editors). Mineralogical Society, London.Google Scholar
Rossel, N.C. (1982) Clay mineral diagenesis in Rotliegend aeolian sandstones of the southern North Sea. Clay Miner. 17, 6977.CrossRefGoogle Scholar
Schultz, L.G., Shepard, A.O., Blackmon, P.D. & Starkey, H.C. (1971) Mixed-layered kaolinite-montmorillonite from the Yucatan Peninsula, Mexico. Clays Clay Miner. 19, 137150.Google Scholar
Shainberg, I. & Otoh, H. (1968) Size and shape of montmorillonite particles saturated with Na/Ca ions, inferred from viscosity and optical measurements. Isr. J. Chem. 6, 251259.Google Scholar
Shaw, B.T. (1942) The nature of colloidal clay as revealed by the electron microscope. J. Phys. Chem. 46, 10321043.Google Scholar
Shimoda, S. (1978) Interstratified minerals. Pp. 265322 in: Clays and Clay Minerals of Japan (Sudo, T. & Shimoda, S., editors). Elsevier, Amsterdam.Google Scholar
Weir, A.H. & Greene-Kelly, R. (1962) Beidellite. Am. Miner. 47, 137146.Google Scholar
Welden, C.M. (1966) A comprehensive petrographic study of the Kalkberg and Tioga bentonites. MSc thesis, Brown Univ. Providence, RI, USA.Google Scholar
Wilson, M.J. & Nadeau, P.H. (1985) Interstratified clay mineral and weathering processes. Pp. 97118 in: The Chemistry of Weathering (Drever, J. I., editor). Reidel Publishing Company, Dordrecht, Netherlands.Google Scholar
Wright, A.C., Granquist, W.I. & Kennedy, J.V. (1972) Catalysis by layer lattice silicates. I. The structure and thermal modification of a synthetic ammonium dioctahedral clay. J. Catalysis 25, 6580.Google Scholar
Yariv, S. & Cross, H. (1979) Geochemistry of Colloid Systems. Springer-Verlag, Berlin, 450 pp.CrossRefGoogle Scholar