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Palladium minerals from the Cauê iron mine, Itabira District, Minas Gerais, Brazil

Published online by Cambridge University Press:  05 July 2018

Gema Ribeiro Olivo
Affiliation:
Université du Québec à Montréal, Département des sciences de la terre, case postale 8888, succ. A, Montréal, PQ, Canada, H3C 3P8
Michel Gauthier
Affiliation:
Université du Québec à Montréal, Département des sciences de la terre, case postale 8888, succ. A, Montréal, PQ, Canada, H3C 3P8

Abstract

Palladium-bearing minerals from the Cauê iron mine, Itabira District, Minas Gerais, Brazil, are found in gold-rich jacutinga, a hydrothermally-altered Lake Superior-type carbonate-bearing oxide facies iron-formation. Palladium occurs as: native palladium with trace contents of Au, Fe and Cu; palladseite ((Pd,Cu,Hg)17Se15), which was found in the core of a grain of palladium; palladium–copper oxide ((Pd,Cu)O); and arsenopalladinite (Pd8(As,Sb)3), with inclusions of palladium–copper oxide. The palladium and palladium–copper oxide grains are coated with films of gold and commonly do not exceed 100 µm in width. These palladium minerals occur in hematite bands and in boudinaged bands of quartz and white phyllosilicate parallel to the S1 mylonitic foliation. Palladium-copper oxide also occurs as inclusions in gold grains which are strongly to weakly stretched parallel to S1.

Palladium mineralization is interpreted as synchronous with intense D1 shearing and contemporaneous with the peak of thermal metamorphism. At high oxygen fugacities and high temperatures (up to 600°C), Pd may have been transported as chloride complexes and deposited following changes in pH caused by mineralizing fluids reacting with jacutinga. Deposition may also have been prompted by the formation of insoluble selenide and arsenide–antimonide minerals and by the dilution of C1 concentrations in the mineralizing fluid. Textural studies, and the zonation observed in palladium and other hydrothermal minerals, suggest that oscillations in the physico-chemical conditions of hydrothermal fluids occurred during the mineralizing event.

Type
Mineralogy
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1995

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References

Cabri, L.J., Clark, A.M., and Chen, T.T. (1977) Arsenopalladinite from Itabira, Brazil, and from the Stillwater Complex, Montana. Canad. Mineral., 15, 70–73.Google Scholar
Clark, A.M., Criddle, A.J. and Fejer, E.E. (1974). Palladium arsenide-antimonides from Itabira, Minas Gerais, Brazil. Mineral Mag., 39, 528–43.CrossRefGoogle Scholar
Davis, R.J., Clark, A.M. and Criddle, A.J. (1977). Palladseite, a new mineral from Itabira, Minas Gerais, Brazil. Mineral. Mag., 41, 123.CrossRefGoogle Scholar
Gammons, C.H., Bloom, M.S. and Yu, Y. (1992) Experimental investigations of the hydrothermal geochemistry of platinum and palladium: I. Solubility of platinum and palladium sulfide minerals in NaCl/H2SO4 solutions at 300°C. Geochim. Costno-chim Ada, 56, 3881–94.CrossRefGoogle Scholar
Henley, R.W. (1973) Solubility of gold in hydrothermal chloride solutions. Chem. Geol., 11, 73–87.CrossRefGoogle Scholar
Hoefs, J., Muller, G. and Schuster, A.K. (1982) Polymetamorphic relations in iron ores from Iron Quadrangle, Brazil: the correlation of oxygen isotope variations with deformation history. Contrib. Mineral. Petrol, 79, 241–51.CrossRefGoogle Scholar
Ineson, P.R. (1989) Introduction to practical ore microscopy. Longman Earth Science Series, John Wiley & Sons, Inc., New York, 181 pp.Google Scholar
Jedwab, J., Cassedanne, J., Criddle, A.J., Ry P., Ghysens, G., Meisser, N., Piret, P. and Stanley, C.J. (1993) Rediscovery of palladinite PdO from Itabira (Minas Gerais, Brazil) and from Ruwe (Shaba, Zaire). Abstract Supplement no. 3, Terra Nova, 5, p. 21.Google Scholar
Leao De Sa, E. and Borges, N.R.A. (1991) Gold mineralization in Caue and Conceicao iron ore mines, Itabira-MG. Field guide book of Brazil Gold'91: An international symposium on the geology of gold. (Fleisher, R., Grossi Sad, J.H., Fuzikawa, K., Ladeira, E. A, eds), pp. 74–85.Google Scholar
Mountain, B.W. and Wood, S.A. (1988) Chemical controls on the solubility, transport, and deposition of platinum and palladium in hydrothermal solu-tions: a thermodynamic approach. Econ. Geol, 83, 492–510.CrossRefGoogle Scholar
Olivo, G.R., Gauthier, M. and Bardoux, M. (1994) Palladian gold from the Caue iron mine, Itabira District, Minas Gerais, Brazil. Mineral. Mag., 58, pp. 579-87.CrossRefGoogle Scholar
Olivo, G.R., Gauthier, M., Bardoux, M., Leao De Sa, E., Fonseca, J.T.F., Santana, F.C. (1995) Palladium-bearing gold deposit hosted by Proterozoic Lake Superior-type iron-formation at CauS iron mine, Itabira district, Southern Sao Francisco Craton, Brazil: geologic and structural controls. Econ. Geol., 90, 118–34.CrossRefGoogle Scholar
Seward, T.M. (1984) The transport and deposition of gold in hydrothermal systems. In Proceedings of the Symposium Gold'82: the geology, geochemistry and genesis of gold deposits (Foster, R.P., ed.). A. A. Balkema, Rotterdam, pp. 165-81.Google Scholar
Wilde, A.R., Bloom, A.S. and Wall, V.J. (1989) Transport and deposition of gold, uranium and platinum-group elements in unconformity-related uranium deposits. Econ. Geol. Monogr. 6, 637–60.Google Scholar