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Thermal decomposition ractions of caledonite and their products

Published online by Cambridge University Press:  05 July 2018

D. J. Morgan
Affiliation:
British Geological Survey, 64-78 Gray’s Inn Road, London WC1X 8NG
S. St. J. Warne
Affiliation:
Department of Geology, University of Newcastle, New South Wales 2308, Australia
S. B. Warrington
Affiliation:
Stanton Redcroft Ltd., Copper Mill Lane, London SW17 0BN
P. H. A. Nancarrow
Affiliation:
British Geological Survey, 64-78 Gray’s Inn Road, London WC1X 8NG

Abstract

The thermal decomposition of caledonite has been examined by simultaneous differential thermal analysis, thermogravimetry and mass spectrometry. Structural H2O and CO2 are liberated endothermically between 300 and 400°C leaving a residue of lead sulphate, oxysulphate, and Cu(I) and Cu(II) oxides. A series of sharp endothermic peaks between 850 and 950°C correspond to phase transition and melting reactions of the PbO-PbSO4 mixture. The sulphate anion breaks down above 880 °C. Mass spectra of the gaseous decomposition products show SO2, SO, and O2, although SO is an artefact arising from ion fragmentation of the SO2 within the mass spectrometer. The residue at 1060 °C is composed predominantly of 2PbO · PbSO4 and Cu(I) and Cu(II) oxides.

Type
Mineralogy
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1986

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References

Billhardt, H.W. (1970) New data on basic lead sulfates. J. Electrochem. Soc: Solid State Sci. 117, 690-2.CrossRefGoogle Scholar
Bugajska, M., and Karwan, T. (1979) Characteristics of the oxidation products of spherical samples of lead sulphide in the temperature range 773-1023 K. Thermochim. Ada. 33, 41-50.CrossRefGoogle Scholar
Collins, L.W., Gibson, E.K., and Wendlandt, W.W. (1974) The composition of evolved gases from the thermal decomposition of certain metal sulfates. Ibid. 9, 15-21.CrossRefGoogle Scholar
Giacovazzo, C, Menchetti, S., and Scordari, F. (1973) The crystal structure of caledonite, Cu2Pb5(SO4)3CO3 (OH)6. Ada Crystallogr. B29, 1989-90.Google Scholar
Gray, N.B., Stump, N.W., Boundy, W.S., and Culver, R.V. (1967) The sulfation of lead sulfide. Trans. Metallurgical Soc. A1ME. 239, 1835-40.Google Scholar
Greenwood, N.N., and Earnshaw, A. (1984) Chemistry of the Element. p. 824. Oxford, Pergamon Press.Google Scholar
Henmi, H., Hirayama, T., Mizutani, N., and Kato, M. (1985) Thermal decomposition of basic copper carbonate, CuCO3. Cu(OH)2 • H2O, in carbon dioxide atmosphere (0-50 atm.). Thermochim. Ada. 96, 145-53.CrossRefGoogle Scholar
Livingstone, A., and Sarp, H. (1984) Macphersonite, a new mineral from Leadhills, Scotland, and Saint-Prix, France—a polymorph of leadhillite and susannite. Mineral. Mag. 48, 277-82.CrossRefGoogle Scholar
Lombardi, G. (1984) Thermal analysis in the investigation of zeolitized and altered volcanics of Latium, Italy. Clay Minerals. 19, 789-801.CrossRefGoogle Scholar
Milodowski, A.E., and Morgan, D.J. (1984) Thermal reactions of leadhillite Pb4SO4(CO3)2(OH)2. Ibid. pp. 825-41.CrossRefGoogle Scholar
Moenke, H. (1974) Mineral Spektre. 1. Akademie-Verlag, Berlin.Google Scholar
Morgan, D.J. (1977) Simultaneous DTA-EGA of minerals and natural mineral mixtures. J. Thermal Anal. 12, 245-63.CrossRefGoogle Scholar
Russell, J.D., Milodowski, A.E., Fraser, A.R., and D. R. (1983) New IR and XRD data for leadhillite of ideal composition. Mineral. Mag. 47, 371-5.CrossRefGoogle Scholar
Fraser, A.R., and Livingstone, A. (1984) The infrared spectra of the three polymorphs of Pb4SO4(CO3)2 (OH)2 (leadhillite, susannite, and macphersonite). Ibid. 48, 295-7.Google Scholar
Stern, K.H., and Weise, E.L. (1966) High-temperature properties and decomposition of inorganic salt. Part 1. Sulfates.NSRDS-NBS 7. US Dept. of Commerce, Washington, USA, 38 pp.Google Scholar
Truex, T.J., Hammerle, R.H., and Armstrong, R.A. (1977) The thermal decomposition of aluminum sulfate. Thermochim. Ada. 19, 301-4.CrossRefGoogle Scholar