Thermogravimetric Analysis of Clay and Clay-Like Minerals

Richard C. Mielenz; N. Cyril Schieltz; Myrle E. King

doi:10.1346/CCMN.1953.0020124

Abstract

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The thermogravimetric method offers a new approach to the study of clay and clay-like minerals as well as other minerals and compounds that gain or lose weight upon heating. This method is complementary to differential thermal analysis, which records energy gains or losses upon heating. Thermogravimetric curves for clay and clay-like minerals are presented and correlated with curves obtained by the differential thermal method. The apparatus, procedures, limitations, and application of the method are described and illustrated.

References

Beck, C. W. (1950) An amplifier for differential thermal analysts: Am. Mineral., v. 35, p. 508–524.Google Scholar

Chevenard, P., Waché, X., and de La Tullage, R. (1944) Etude de la corrosion seche des metaux au moyen d'une thermobalance: Soc. Chimique de France, Bull., Section 5, v. 11, p. 41–47.Google Scholar

De Keyser, W. L. (1953) Differential thermobalance: A new research tool: Nature, v. 172, p. 364.CrossRef Google Scholar

Duval, C. (1951) Continuous weighing in analytical chemistry: Anal. Chem., v. 23, p. 1271–1286.CrossRef Google Scholar

Duval, C. (1953) Inorganic thermogravimetric analysis: Elsevier Publishing Co., New York, N. Y., 531 p.Google Scholar

Grim, R. E., and Rowlands, R. A. (1942) Differential thermal analysis of clay minerals and other hydrous materials: Am. Mineral., v. 27, p. 746–761 and 801-818.Google Scholar

Kerr, P. F., and Kulp, J. L. (1948) Multiple differential thermal analysis: Am. Mineral, v. 33, p. 387–419.Google Scholar

Migeon, G. (1936) Contribution a l’étude de la definition des Sepiolites: Soc. franc. Mineral., Bull., v. 59, p. 6–133.Google Scholar

Nutting, P. G. (1943) Some standard thermal dehydration curves of minerals: U. S. Geol. Survey, Bull. 197-E, p. 197–216.Google Scholar

Spiel, S. (1945) Applications of thermal analysis to clays and aluminous minerals: U. S. Bur. Mines, R. I. 3764, 36 p.Google Scholar

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Mielenz, Richard C. Schieltz, N. Cyril and King, Myrle E. 1954. Effect of Exchangeable Cation on X-Ray Diffraction Patterns and Thermal Behavior of a Montmorillonite Clay. Clays and clay minerals (National Conference on Clays and Clay Minerals), Vol. 3, Issue. , p. 146.

Nagy, Bartholomew Meinschein, Warren G. and Hennessy, Douglas J. 1963. AQUEOUS, LOW TEMPERATURE ENVIRONMENT OF THE ORGUEIL METEORITE PARENT BODY. Annals of the New York Academy of Sciences, Vol. 108, Issue. 2, p. 534.

Sen, P. C. Dutt, Ashimesh and Rao, H. V. Bhaskar 1973. Thermal Dehydroxylation and Phase Transformation of Bayer's Alumina. Transactions of the Indian Ceramic Society, Vol. 32, Issue. 3, p. 60.

DePuy, GW 1990. Petrography Applied to Concrete and Concrete Aggregates. p. 32.

Morales Carrera, Ana Mercedes Varajão, Angélica Fortes Drummond Chicarino and Gonçalves, Marcos Andrade 2008. Caracterização Mineralógica das Argilas da Península de Santa Elena, Equador. Rem: Revista Escola de Minas, Vol. 61, Issue. 1, p. 97.

Zhang, Minwei Tang, Junwu Song, Qingjun and Dong, Qing 2010. Backscattering ratio variation and its implications for studying particle composition: A case study in Yellow and East China seas. Journal of Geophysical Research: Oceans, Vol. 115, Issue. C12,

Bardelli, Fabrizio Mondelli, Claudia Didier, Mathilde Vitillo, Jenny G. Cavicchia, Demetrio R. Robinet, Jean-Charles Leone, Laura and Charlet, Laurent 2014. Hydrogen uptake and diffusion in Callovo-Oxfordian clay rock for nuclear waste disposal technology. Applied Geochemistry, Vol. 49, Issue. , p. 168.

Elert, Kerstin Pardo, Eduardo Sebastián and Rodriguez-Navarro, Carlos 2015. Alkaline activation as an alternative method for the consolidation of earthen architecture. Journal of Cultural Heritage, Vol. 16, Issue. 4, p. 461.

Barshad, Isaac 2015. Methods of Soil Analysis. p. 699.

Mondelli, Claudia Bardelli, Fabrizio Vitillo, Jenny G. Didier, Mathilde Brendle, Jocelyne Cavicchia, Demetrio R. Robinet, Jean-Charles and Charlet, Laurent 2015. Hydrogen adsorption and diffusion in synthetic Na-montmorillonites at high pressures and temperature. International Journal of Hydrogen Energy, Vol. 40, Issue. 6, p. 2698.

Plater, Andrew J. Kirby, Jason R. Boyle, John F. Shaw, Timothy and Mills, Hayley 2015. Handbook of Sea‐Level Research. p. 312.

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Fanning, Delvin S. Keramidas, Vissarion Z. and El-Desoky, Mohamed A. 2018. Minerals in Soil Environments. p. 551.

Ashrit, Shrenivas Chatti, Ravikrishna V. Nair, Udayabhanu G. and Rayasam, Venugopal 2018. Study of thermogravimetric curves of LD Slag size fractions in oxygen and nitrogen atmosphere and effect of FeO and free lime on weight loss at different temperatures. Metallurgical Research & Technology, Vol. 115, Issue. 4, p. 417.

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Thermogravimetric Analysis of Clay and Clay-Like Minerals

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