The thermal decomposition of chrysotile

C. J. Martin

doi:10.1180/minmag.1977.041.320.05

Summary

The decomposition of chrysotile fibres heated in air has been studied in the range 100–1400°C by electron microscopy and infra-red absorption. The first observable change in the structure occurred at 580°C, where cavities started to open up between the (001) layers of chrysotile as the fibres were dehydrated, giving rise to strong low-angle diffraction. There was no evidence of any structure in the remaining material but some degree of the original atomic arrangement was preserved for the magnesium silicates, forsterite, and enstatite, later developed in certain preferred orientations. The manner of this crystallization was determined by the thermal treatment, for in samples held between 600°C and 800°C forsterite developed slowly with little further disruption of the fibre while above 800°C the remaining amorphous areas rapidly recrystallized to a mixture of forsterite and enstatite. It is suggested that the mechanisms described by other investigators to explain the development of forsterite in preferred orientations may serve simply to nucleate the crystallization and a similar mechanism to account for the nucleation of the enstatite crystallization is considered. At high temperatures a possible doubling of some of the lattice parameters of the silicates was observed.

Footnotes

Present address: Department of Medical Physics, University of Aberdeen, AB9 2ZD.

References

Ball, (M. C.) and Taylor, (H. F. W.), 1963. Mineral. Mag. 33, 467–82 [M.A. I6-624].Google Scholar

Brindley, (G. W.) and Hayami, (R.), 1965. Ibid. 35, 189–95 [MA 17-134].Google Scholar

Brindley, (G. W.) and Zussman, (J.), 1957. Am. Mineral. 42, 461–74 [M.A. I3-545].Google Scholar

Johns, (W. D.), 1965. Ceram. Bull. 44, 682–6.Google Scholar

Martinez, (E.), 1961. Am. Mineral. 46, 901–12 [M.A. 15-544].Google Scholar

Smyth, (J. R.), 1974. Ibid. 59, 345–52 [M.A. 26-283].Google Scholar

Whittaker, (E. J. W.) and Zussman, (J.), 1971. The Electron Optical Investigation of Clays, (ed. J. A. Gard). London (Mineralogical Society), ch. 5, 173–5 [M.A. 23-65].Google Scholar

Yada, (K.), 1967. Ada Crystallogr. 23, 704–7 [M.A. 2O-529].CrossRef Google Scholar

Yada, (K.), 1971. Ibid. A27, 659–64 [M.A. 23-I8I6].Google Scholar

Crossref Citations

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Germine, Mark and Puffer, John H. 1981. Distribution of asbestos in the bedrock of the northern New Jersey area. Environmental Geology, Vol. 3, Issue. 6, p. 337.

Datta, A K Samantaray, B K and Bhattacherjee, S 1986. Thermal transformation in a chrysotile asbestos. Bulletin of Materials Science, Vol. 8, Issue. 4, p. 497.

Datta, A K Mathur, B K Samantaray, B K and Bhattacherjee, S 1987. Dehydration and phase transformation in chrysotile asbestos—A radial distribution analysis study. Bulletin of Materials Science, Vol. 9, Issue. 2, p. 103.

Datta, A. K. 1991. Dehydration of chrysotile asbestos: an infrared absorption study. Journal of Materials Science Letters, Vol. 10, Issue. 15, p. 870.

Faust, J. and Williams, Q. 1996. Infrared spectra of phase B at high pressures: Hydroxyl bonding under compression. Geophysical Research Letters, Vol. 23, Issue. 5, p. 427.

Ilgren, E. B. 2004. Coalinga Chrysotile: A Short Fibre, Amphibole Free, Chrysotile: Part V - Lack of Amphibole Asbestos Contamination. Indoor and Built Environment, Vol. 13, Issue. 5, p. 325.

Gualtieri, Alessandro F. Gualtieri, Magdalena Lassinantti and Tonelli, Massimo 2008. In situ ESEM study of the thermal decomposition of chrysotile asbestos in view of safe recycling of the transformation product. Journal of Hazardous Materials, Vol. 156, Issue. 1-3, p. 260.

Malkov, A. A. Korytkova, E. N. Maslennikova, T. P. Shtykhova, A. M. and Gusarov, V. V. 2009. Effect of heat treatment on structural-chemical transformations in magnesium hydrosilicate [Mg3Si2O5(OH)4] nanotubes. Russian Journal of Applied Chemistry, Vol. 82, Issue. 12, p. 2079.

Burzo, E. 2009. Phyllosilicates. Vol. 27I5b, Issue. , p. 258.

Dellisanti, Francesco Rossi, Piermaria L. and Valdrè, Giovanni 2009. Remediation of asbestos containing materials by Joule heating vitrification performed in a pre-pilot apparatus. International Journal of Mineral Processing, Vol. 91, Issue. 3-4, p. 61.

Anastasiadou, Kalliopi Axiotis, Dimosthenis and Gidarakos, Evangelos 2010. Hydrothermal conversion of chrysotile asbestos using near supercritical conditions. Journal of Hazardous Materials, Vol. 179, Issue. 1-3, p. 926.

Ryu, Kyoung Won Jang, Young Nam and Lee, Myung Gyu 2012. Enhancement of Chrysotile Carbonation in Alkali Solution. MATERIALS TRANSACTIONS, Vol. 53, Issue. 7, p. 1349.

Kusiorowski, R. Zaremba, T. Piotrowski, J. and Adamek, J. 2012. Thermal decomposition of different types of asbestos. Journal of Thermal Analysis and Calorimetry, Vol. 109, Issue. 2, p. 693.

Kusiorowski, R. Zaremba, T. Piotrowski, J. and Gerle, A. 2013. Thermal decomposition of asbestos-containing materials. Journal of Thermal Analysis and Calorimetry, Vol. 113, Issue. 1, p. 179.

Trittschack, Roy Grobéty, Bernard and Brodard, Pierre 2014. Kinetics of the chrysotile and brucite dehydroxylation reaction: a combined non-isothermal/isothermal thermogravimetric analysis and high-temperature X-ray powder diffraction study. Physics and Chemistry of Minerals, Vol. 41, Issue. 3, p. 197.

Dlugogorski, Bogdan Z. and Balucan, Reydick D. 2014. Dehydroxylation of serpentine minerals: Implications for mineral carbonation. Renewable and Sustainable Energy Reviews, Vol. 31, Issue. , p. 353.

Kusiorowski, Robert Zaremba, Teresa Gerle, Anna Piotrowski, Jerzy Simka, Wojciech and Adamek, Jakub 2015. Study on the thermal decomposition of crocidolite asbestos. Journal of Thermal Analysis and Calorimetry, Vol. 120, Issue. 3, p. 1585.

Unluer, C. and Al-Tabbaa, A. 2015. The role of brucite, ground granulated blastfurnace slag, and magnesium silicates in the carbonation and performance of MgO cements. Construction and Building Materials, Vol. 94, Issue. , p. 629.

Montoya, Alejandro and Haynes, Brian S. 2015. Energy profiles of hydrogen migration in the early stages of lizardite dehydroxylation. Computational Materials Science, Vol. 98, Issue. , p. 435.

Bloise, Andrea Catalano, Manuela Barrese, Eugenio Gualtieri, Alessandro Francesco Bursi Gandolfi, Nicola Capella, Silvana and Belluso, Elena 2016. TG/DSC study of the thermal behaviour of hazardous mineral fibres. Journal of Thermal Analysis and Calorimetry, Vol. 123, Issue. 3, p. 2225.

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The thermal decomposition of chrysotile

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