The role of water vapour in the dehydroxylation of clay minerals

G. W. Brindley; M. Nakahira

doi:10.1180/claymin.1957.003.17.01

Abstract

Water vapour atmospheres are known to raise the temperature of the endothermic reaction of clay minerals in differential thermal analyses. In isothermal kinetic studies of dehydroxylation, it is shown that a stationary state is attained depending on the operating temperature. The rate of dehydroxylation is a function of specimen size and shape, which suggests a controlling influence by entrapped water vapour. Even at constant reaction temperatures, the rate of dehydroxylation varies greatly between the interior and the exterior of a specimen. The bearing of these results on thermal analyses and on kinetic studies generally is discussed.

References

Brindley, G. W. and Nakahira, M. 1957. Clays and Clay Minerals (Fifth National Conference) in press.Google Scholar

Murray, P. and White, J. 1949. Clay Min. Bull., 1, 84–7.CrossRef Google Scholar

Murray, P. and White, J. 1949. Trans. Brit. Ceram. Soc, 48, 187–206.Google Scholar

Murray, P. and White, J. 1955. Trans. Brit. Ceram. Soc, 54, 137–238.Google Scholar

Murray, P. and White, J. 1955. Clay Min. Bull., 2, 255–64.CrossRef Google Scholar

Pieters, H. A. 1928. Thesis (Delft, Netherlands).Google Scholar

Roy, R. and Osborn, E. F. 1954. Amer. Min., 39, 853–85.Google Scholar

Roy, R. and Brindley, G. W. 1956. Clays and Clay Minerals (Fourth National Conference), 125–32.Google Scholar

Stone, R. L. 1952. J. Amer. ceram. Soc, 35, 90–99.CrossRef Google Scholar

Stone, R. L. 1954. Clays and Clay Minerals (Second National Conference), 315–23.Google Scholar

Stone, R. L. and Rowland, R. A. 1955. Clays and Clay Minerals (Third Nation al Conference), 103–16.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Brindley, G. W. and Millhollen, G. L. 1966. Chemisorption of Water at High Temperatures on Kaolinite: Effect on Dehydroxylation. Science, Vol. 152, Issue. 3727, p. 1385.

JOHNSON, HOWARD B. and KESSLER, FRANK 1969. Kaolinite Dehydroxylation Kinetics. Journal of the American Ceramic Society, Vol. 52, Issue. 4, p. 199.

Brindley, G. W. 1983. Can a rate constant independent of sample size be obtained from the rate equation generally used in thermal analysis?. Journal of Thermal Analysis, Vol. 27, Issue. 2, p. 443.

Cabrera, J.G. and Eddleston, M. 1983. Kinetics of dehydroxylation and evaluation of the crystallinity of kaolinite. Thermochimica Acta, Vol. 70, Issue. 1-3, p. 237.

Wilson, Michael A. Young, Brian C. and Scott, Keith M. 1986. Coal pyrolysis residue analysis by 27Al and 29Si nuclear magnetic resonance spectrometry. Fuel, Vol. 65, Issue. 11, p. 1584.

Elzea, J.M. Odom, I.E. and Miles, W.J. 1994. Distinguishing well ordered opal-CT and opal-C from high temperature cristobalite by x-ray diffraction. Analytica Chimica Acta, Vol. 286, Issue. 1, p. 107.

Dion, P. Alcover, J.-F. Bergaya, F. Ortega, A. Llewellyn, P. L. and Rouquerol, F. 1998. Kinetic study by controlled-transformation rate thermal analysis of the dehydroxylation of kaolinite. Clay Minerals, Vol. 33, Issue. 2, p. 269.

Arsenović, Milica Pezo, Lato Mančić, Lidija and Radojević, Zagorka 2014. Thermal and mineralogical characterization of loess heavy clays for potential use in brick industry. Thermochimica Acta, Vol. 580, Issue. , p. 38.

Drebushchak, V. A. Mylnikova, L. N. and Drebushchak, T. N. 2018. Thermoanalytical investigations of ancient ceramics. Journal of Thermal Analysis and Calorimetry, Vol. 133, Issue. 1, p. 135.

Sullivan, Matthew S. Chorzepa, Mi G. Hamid, Hiwa Durham, Stephan A. and Kim, S. Sonny 2018. Sustainable Materials for Transportation Infrastructures: Comparison of Three Commercially-Available Metakaolin Products in Binary Cementitious Systems. Infrastructures, Vol. 3, Issue. 3, p. 17.

Kamal, Nagla Kochkodan, Viktor Zekri, Atef and Ahzi, Said 2019. Polysulfone Membranes Embedded with Halloysites Nanotubes: Preparation and Properties. Membranes, Vol. 10, Issue. 1, p. 2.

Maruvanchery, Varun and Kim, Eunhye 2020. Effects of a High Temperature (500 °C) on the Fracture Processes in Calcite-Cemented Sandstone Along Bedding-Plane Orientations. Rock Mechanics and Rock Engineering, Vol. 53, Issue. 2, p. 955.

Santos, Tiago Gomes, Celso S. F. Hennetier, Luc Costa, Vítor A. F. and Costa, Luís C. 2021. Global insight into microwave stoneware firing: Macro and microstructural changes. International Journal of Applied Ceramic Technology, Vol. 18, Issue. 5, p. 1801.

Santos, T. Gomes, C. S. F. Costa, V. A. F. and Costa, L. C. 2021. Microwave Versus Conventional Porcelain Firing: Greenware to Biscuit Crystallochemical Transformations. Journal of Manufacturing Science and Engineering, Vol. 143, Issue. 12,

Santos, T. Gomes, C.S.F. Santos, N.F. Costa, V.A.F. and Costa, L.C. 2022. Global insight into microwave stoneware firing: Crystallochemical transformations. Ceramics International, Vol. 48, Issue. 15, p. 21492.

Santos, T. Hennetier, L. Costa, V.A.F. and Costa, L.C. 2022. Microwave versus conventional porcelain firing: Colour analysis. Materials Chemistry and Physics, Vol. 275, Issue. , p. 125265.

Santos, Tiago A. C. Costa, Vítor A. F. and Costa, Luís M. C. M. 2023. Microstructure analysis of microwave and conventionally fired porcelain. Fire and Materials, Vol. 47, Issue. 3, p. 375.

Article contents

The role of water vapour in the dehydroxylation of clay minerals

Abstract

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The role of water vapour in the dehydroxylation of clay minerals

Abstract

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests