Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-28T17:37:39.390Z Has data issue: false hasContentIssue false

Properties of soil kaolins from Thailand

Published online by Cambridge University Press:  09 July 2018

R. D. Hart*
Affiliation:
Department of Soil Science and Plant Nutrition, University of Western Australia, Perth, Western Australia6907
W. Wiriyakitnateekul*
Affiliation:
Department of Soil Science and Plant Nutrition, University of Western Australia, Perth, Western Australia6907
R. J . Gilkes
Affiliation:
Department of Soil Science and Plant Nutrition, University of Western Australia, Perth, Western Australia6907
*
Soil Analysi s Division Land Development Department, Bangkok, Thailand, 10900

Abstract

Purified kaolins from Thai soil on diverse parent materials were characterized using analytical transmission electon microscopy, X-ray diffraction, thermogravimetric analysis and chemical analysis. The properties of Thai soil kaolins appear to be more diverse than Indonesian and Western Australian soil kaolins investigated using the same analytical procedures; this difference may reflect the greater range of parent materials for the Thai soils. The kaolins show a variety of crystal morphologies including euhedral hexagonal to subhedral platy crystals, tubes and laths and several morphologies were present in most samples. TEM-EDS enabled analysis of single crystals of each morphology present within a sample. Tubular or lath-shaped crystals usually have lower %Fe2O3 contents than hexagonal platy crystals in the same sample. The relationships between crystal size and Fe content within morphological populations were also examined by TEM-EDS. Generally, smaller kaolin crystals display a wider range of Fe concentration than the larger kaolin crystals in the same sample. Increasing Fe concentration in bulk samples is closely correlated to decreasing coherently scattering domain size (R2 = 0.57), increasing cation exchange capacity (R2 = 0.44) and increasing specific surface area (R2 = 0.65). However the properties of the deferrated soil kaolins, including their Fe content, are not related to forms of Fe, (total Fe, amorphous or organic) in the untreated clay fraction of the soil.

Inhibited vermiculite is a common minor constituent of these clay fractions and its average structural formula derived from EDS data indicates that it was formed by Al replacing K in muscovite. One Al3+ ion occupies the interlayer space previously occupied by three K+ ions. As the distances between these Al3+ cations in the interlayer space is large it is proposed that isolated or loosely associated hydrated Al3+ groups such as Al(OH2)63+ exist that resist exchange by other cations due to hydrogen bonding with the adjacent tetrahedral oxygen surfaces

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2003

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Allen, B.L. & Hajek, B.F. (1989) Mineral occurrence in soil environments. Pp. 220225 in: Minerals in Soil Environments, 2nd edition (Dixon, J.B. and Weed, S.B., editors). Soil Science Society of America, Madison, Wisconsin, USA.Google Scholar
Aylmore, L.A.G., Sills, I.D. & Quirk, J.P. (1970) Surface area of homoionic illite and montmorillonite clay minerals as measured by the sorption of nitrogen and carbon dioxide. Clays and Clay Minerals, 18, 9196.Google Scholar
Bailey, S.W. (1990) Halloysite – A critical assessment. Proc eed ings of the 9th Interna tional Clay Conference, Strasbourg, 1989 (Farmer, V.C. and Tardy, Y., editors). Sci. Geol. Mem. 86, 8998.Google Scholar
Barshad, I. & Kishk, F.M. (1969) from Douglas, L.A. (1989) Mineral occurrence in soil environments. P. 644 in: Minerals in Soil Environments, 2nd edition (Dixon, J.B. and Weed, S.B., editors). Soil Science Society of America, Madison, Wisconsin, USA.Google Scholar
Bates, T.F., Hilderbrand, F.A. & Swineford, A. (1950) Morphology and structure of endellite and halloysite. American Mineralogist, 35, 463 484.Google Scholar
Bolland, M.D.A., Posner, A.M. & Quirk, J.P. (1976) Surface charge on kaolinites in aqueous suspension. Australian Journal of Soil Research, 14, 197 216.CrossRefGoogle Scholar
Brown, G. & Brindley, G.W. (1980) X-ray diffraction procedures for clay mineral identification. Pp. 305359 in. Crystal Structures of Clay Minerals and their X-ray Identification (Brown, G. and Brindley, G.W., editors). Monograph 5, Mineralogical Society, London.Google Scholar
Brindley, G.W., Kao, C.-C., Harrison, J.L., Lipsicas, M. & Raythatha, R. (1986) Relation between structural disorder and other characteristics of kaolinites and dickites. Clays and Clay Minerals, 34, 239 249.Google Scholar
Brindley, G.W. & Wan, H.M. (1974) Use of long spacing alcohols and alkanes for calibration of long spacings from layer silicates, particularly clay minerals. Clays and Clay Minerals, 22, 313 317.Google Scholar
Cases, J.M., Lietard, O., Yvon, J. & Delon, J.F. (1982) Etude des proprietes cristallochemiques, morphologiques, superficielles, de kaolinites desordonnees. Bulletin de Mineralogie, 105, 439 455.CrossRefGoogle Scholar
Cases, J.M., Cunin, P., Grillet, Y., Poinsignon, C. & Yvon, J. (1986) Methods of analysing morphology of kaolinites: relations between crystallographic and morphological properties. Clay Minerals, 21, 5568.Google Scholar
Delineau, T., Allard, T., Muller, J.-P., Barres, O., Yvon, J. & Cases, J.-M. (1994) FTIR reflectance vs EPR studies of structural iron in kaolinites. Clays and Clay Minerals, 42, 308320.Google Scholar
Dixon, J.B. & Jackson, M.L. (1959) Dissolution of interlayers from intergradient soil clays after preheating at 400ºC. Science, 129, 16161617.CrossRefGoogle Scholar
Dolcater, D.L., Syers, J.K. & Jackson, M.L. (1970) Titanium as free oxide and substituted forms in kaolinites and other soil minerals. Clays and Clay Minerals, 18, 7179.Google Scholar
Fialips, C.-I., Petit, S., Decarreau, A. & Beaufort, D. (2000) Influence of synthesis pH on kaolinite crystallinity and surface properties. Clays and Clay Minerals, 48, 173184.CrossRefGoogle Scholar
Gee, G.W. & Baulder, J.W. (1986) Particle size analysis. Pp. 383411 in. Methods of Soil Analysis Part I (Klute, A., editor). Mongraph No. 9, American Society of Agronomy, Madison, Wisconsin, USA.Google Scholar
Guggenheim, S., Chang, Y.H. & Koster van Groos, A.F. (1987) Muscovite dehydroxylation: High-temperature studies. American Mineralogist, 72, 537550.Google Scholar
Hart, R.D., Gilkes, R.J., Siradz, S. & Singh, B. (2002) The nature of soil kaolins from Indonesia and Western Australia. Clays and Clay Minerals, 50,198 –207.CrossRefGoogle Scholar
Herbillon, A.J., Mestdagh, M.M., Vielvoye, L. & Derouane, E.G. (1976) Iron in kaolinite with special reference to kaolinite from tropical soils. Clay Minerals, 11, 201 220.Google Scholar
Hinkley, D.N. (1963) Variability in ‘crystallinity’ values among kaolin deposits of the coastal plain of Georgia and South Carolina. Proceedings 11th National Clay Conference Ottawa, Canada. Clays and Clay Minerals, 11, 229 235.Google Scholar
Hughes, J.C. & Brown, G. (1979) A crystallinity index for soil kaolins and its relation to parent rock, climate and maturity. Journal of Soil Science, 30, 557563.CrossRefGoogle Scholar
Jepson, W.B. & Rowse, J.B. (1975) The composition of kaolinite – an electron microprobe study. Clays and Clay Minerals, 23, 310317.Google Scholar
Kawano, M., Tomita, K. & Shinohara, Y. (1997) Analytical electron microscopic study of the noncrystalline products formed at the early weathering stages of volcanic glass. Clays and Clay Minerals, 45, 440447.Google Scholar
Kheoruenr omne, I. (1991) Soils of Thai land; Characteristics, Distribution and Uses. Department of Soil Science, Faculty of Agriculture, Kasetsart University, Bangkok.Google Scholar
Klug, H.P. & Alexander, L.E. (1974) X-ray diffraction Procedures for Polycrystalline and Amorphous Materials. John Wiley & Sons Inc., New York & London.Google Scholar
Koppi, A.J. & Skjemstad, J.O. (1981) Soil kaolins and their genetic relationships in southeast Queensland, Australia. Journal of Soil Science, 32, 661 672.Google Scholar
Lorimer, G.W. (1987) Quantitative X-ray microanalysis of thin specimens in the transmission electron microscope; a review. Mineralogical Magazine, 51, 4960.Google Scholar
Ma, C. & Eggleton, R.A. (1999) Cation exchange capacity of kaolinite. Clays and Clay Minerals, 47, 174180.Google Scholar
Ma, C., Fitzgerald, J.D., Eggleton, R.A. & Llewellyn, D.J. (1998) Analytical electron microscopy in clays and other phyllosilicates: loss of elements from a 90 nm stationary beam of 300 keV electrons. Clays and Clay Minerals, 46, 301316.Google Scholar
Malengrau, N., Muller, J.-P. & Callas, G. (1995) Spectroscopic approach for investigating the status and mobility of Ti in kaolinite materials. Clays and Clay Minerals, 43, 615621.CrossRefGoogle Scholar
Mehra, O.P. & Jackson, M.L. (1960) Iron oxide removal from soils and clays by a dithionate-citrate system buffered with sodium bicarbonate. Clays and Clay Minerals, 7, 317327.Google Scholar
Mestdagh, M.M., Vielvoye, L. & Herbillon, A.J. (1980) Iron in kaolinite: II. The relationship between kaolinite crystallini ty and iron content. Clay Minerals, 15, 113.Google Scholar
Muller, J.-P. & Calas, G. (1989) Tracing kaolinites through their defect centres: Kaolinite paragenesis in a laterite (Cameroon). Economic Geology, 84, 694707.Google Scholar
Newman, A.C.D. (1987) The interaction of water with clay mineral surfaces. Pp. 250 in. Chemistry of Clays and Clay Minerals (A.C.D. Newman, editor). Monograph 6, Mineralogical Society London, Longman Scientific and Technical, Harlow, Essex, UK.Google Scholar
Noro, H. (1986) Hexagonal platy halloysite in an altered tuff bed, Komaki City, Aichi Prefecture, central Japan. Clay Minerals, 21, 401415.CrossRefGoogle Scholar
Norrish, K. & Hutton, J.T. (1969) An accurate X-ray spectrographic method for the analysis of a wide range of geologica l samples. Geochimi ca et Cosmochimica Acta, 33, 431453.Google Scholar
Norrish, K. & Pickering, J.G. (1983) Clay Minerals. Pp. 281308 in: Soils, an Australian Viewpoint (Norrish, K. & Pickering, J.G., editors ). CSIRO Melbourne, Academic Press, London.Google Scholar
Oakley, D.M. & Jennings, B.R. (1982) Clay particle sizing by electrically induced birefringence. Clay Minerals, 17, 313325.Google Scholar
Rayment, G.E. & Higginson, E.R. (1992) Australian Laboratory Handbook of Soil and Water Chemical Methods: Austral ian Soil and Land Survey Handbook. Inkata, Melbourne, Australia.Google Scholar
Schroeder, P.A. & Pruett, R.J. (1996) Fe ordering in kaolinite: Insights from 29Si and 27Al MAS NMR spectroscopy. American Mineralogist, 81, 2638.Google Scholar
Saalfeld, H. & Wedde, M. (1974) Refinement of the crystal structure of gibbsite, Al(OH)3. Zeitschrift für Kristallographie, Kristallgeometrie, Kristallphysik, Kristallchemie, 139, 129135.Google Scholar
Schwertmann, U. & Herbillon, A.J. (1992) Some aspects of fertility associated with the mineralogy of highly weathered tropical soils. Pp. 4759 in. Myths and Science of Soils of the Tropics (Lal, R. and Sanchez, P.A., editors). Special Publication 29, Soil Science Society of America, Madison, Wisconsin, USA.Google Scholar
Singh, B. & Gilkes, R.J. (1992a) XPAS: An interactive program to analyse X-ray powder diffraction patterns. Powder Diffraction, 7, 610.Google Scholar
Singh, B. & Gilkes, R.J. (1992b) Properties of soil kaolins from south-western Australia. Journal of Soil Science, 43, 645667.Google Scholar
Singh, B. & Gilkes, R.J. (1995) Application of analytical transmission electron microscopy to identifying intercrystal variations in the composition of clay minerals. Analyst, 120, 13351339.Google Scholar
Smykatz-Kloss, W. (1975) The DTA determination of degree of (dis-) order of kaolinites. Proceedings of the International Clay Conference, Willmette, Illinois, USA, 429438.Google Scholar
Soil Survey Staff (1987) Keys to Soil Taxonomy. SMSS Technical Monograph 6, Cornell University, New York.Google Scholar
Stone, W.E. & Torres-Sanchez, R.-M. (1988) Nuclear magnetic resonance spectroscopy applied to minerals. Journal of the Chemical Society: Faraday Transactions, 84, 117132.Google Scholar
Tazaki, K. (1982) Analytical electron microscopic studies of halloysite formation processes – morphology and composition of halloysite. Proceedings of the 7th Internation al Clay Conference. Italy, pp. 573584, Elsevier Scientific Publishing Co., New York.Google Scholar
Trunz, V. (1976) The influence of crystallite size on the apparent basal spacings of kaolinite. Clays and Clay Minerals, 24, 8487.Google Scholar
Van Olphen, H. (1963) An Introduction to Clay Colloid Chemistry. Wiley Interscience, New York.Google Scholar
Varajao, A.F.D.C., Hart, R.D. & Gilkes, R.J. (2001) The relationships between kaolinite crystal properties and the origin of materials for a Brazilian kaolin deposit. Clays and Clay Minerals, 49, 44 59.Google Scholar
Weaver, C.E. (1976) The nature of TiO2 in kaolinite. Clays and Clay Minerals, 24, 215218.Google Scholar