Mineralization and leaching process in the Jian copper deposit, northeastern Fars province: Application of petrography and stable isotopes

Document Type : Research Article

Authors

1 Shiraz

2 Ferdowsi University of Mashhad

Abstract

Introduction
One of the first principles in the formation of a reserve is mineralogical, construction and mineral textures studies and investigation of paragenetic relations in the ore minerals. In addition, to petrographic studies, isotopic investigates have wide applications in economic geology. In general, copper isotope variability in primary (high temperature) mineralization forms a tight cluster, in contrast to secondary mineralization, which has a much larger isotope range. A distinct pattern of heavier copper isotope signatures is evident in supergene samples, and a lighter signature characterizes the leached cap and oxidation-zone minerals. This relationship has been used to understand oxidation–reduction processes (Hoefs, 2009). Also for a better understanding of the origin of the Jian Cu deposit, this research focuses on the origin and composition of the fluid and elucidation of its evolution during the mineralization process. In order to achieve this end, field observations, vein petrography, microthermometry of fluid inclusions and stable isotope analyses of veins and minerals were investigated. The present study also compares high and low temperature sulfide samples in an attempt to document and explain diagnostic δ65Cu ranges in minerals from the Jian deposit.

Materials and methods
The samples were taken from different depths to measure Cu isotope variations within each reservoir. Mineralogical composition was determined using X-ray diffractometry. In addition, chromatographic separation was carried out on all samples (except for native Cu samples) in a clean lab and was conducted as outlined in Mathur et al. (Mathur et al., 2009). These samples were measured into a Multicollector Inductively-Coupled-Plasma Mass Spectrometer (MC-ICPMS, the Micro mass Isoprobe at the University of Arizona) in low resolution mode using a microconcentric nebulizer to increase sensitivity for the samples with lower concentrations of copper. Preparation and analysis of quartz for oxygen isotopes was performed using the standard techniques detailed by Clayton and Mayeda (Clayton and Mayeda, 1963). Fluid inclusions were extracted for δD measurement from quartz samples selected as far as possible to avoid late inclusions. The methods were standard and similar to those published in Fallick et al. (Fallick et al., 1987). Stable isotope analysis for oxygen and hydrogen isotopes was undertaken at the isotope geochemistry laboratory, University of Queensland.

Results
δ65Cu values for analyzed samples range from -0.45 to +0.49 ‰ in the secondary copper minerals (malachite). The δ18O values for analyzed quartz samples, collected from different quartz veins of the Jian deposit, fall in a narrow range varying from +15.8 to +18.4‰ (avg. +16.7‰) for type A veins and +16.6 to +17.9‰ (avg. +17.2‰) for type B veins. The δ18O values of the fluids calculated from the Jian quartz samples range from +7.6 to +10.7‰ (avg. +9.1 ‰) for type A veins and +4.7 to +5.1‰ (avg. +4.9 ‰) for type B veins. The δD values of the fluid inclusions hosted by quartz samples range from -33.1 to -41.2‰ (avg. -37.6‰) for type A and -52.3 to -54.9‰ (avg. -53.1‰) for type B veins.

Discussion
Based on mineralization style and structures, Th, salinity and composition of fluid inclusions, stable isotope systematics, timing of the mineralization with respect to deformation and metamorphism, host rocks, ore and gangue minerals, the Jian deposit can be classified either as a metamorphogenic or mesothermal Cu-bearing quartz deposit. Precipitation of secondary Cu+-sulfide minerals from the Cu+ complexes present in this fluid would result in sulfide minerals with low copper isotopic variations (-0.45 to +0.49‰) in the Jian copper deposit. This could explain why a low variation in the isotopic composition of Cu is observed in a horizontal plane. Isotopically, mineralization is most probably the result of varied isotopic fractionation processes including low copper leaching, Cu+ to Cu2+ oxidation-reduction reactions, and fluid-mineral fractionations. Oxygen and hydrogen isotope compositions suggest that the main metallization occurred from a metamorphic dehydration in type A veins. These sulfide-bearing quartz veins are interpreted as a small-scale example of redistribution of mineral deposits by metamorphic fluids. This study suggests that mineralization at Jian is interpreted as metamorphogenic in style, probably related to a deep-seated mesothermal system.

Acknowledgements
The authors would like to thank Managing director of the Jian Corporation Ltd. for his help during fieldwork and sampling. Logistical and financial supports were provided by Department of Earth Sciences, Faculty of Sciences, Shiraz University.

References
Clayton, R.N., and Mayeda, T.K., 1963. The use of bromine pentafluoride in the extraction of oxygen from oxides and silicates for isotopic analysis. Geochimica et Cosmochimica Acta, 27(1): 43-52.
Fallick, A.E., Jocelyn, J., and Hamilton, P.J., 1987. Oxygen and hydrogen stable isotope systematics in Brazilian agates, In: R. Rodriguez-Clemente (Editor), Geochemistry of the earth surface and processes of mineral formation. Instituto de Geologia (Consejo Superior de Investigaciones Científicas-Spanish National Research Council), Madrid, pp. 99-117.
Hoefs, J., 2009. Stable Isotope Geochemistry. Springer, Amsterdam, 203 pp.
Mathur, R., Titley, S., Barra, F., Brantley, S., Wilson, M., Phillips, A., Munizaga, F., Maksaev, V., Vervoort, J. and Hart, G., 2009. Exploration potential of Cu isotope fractionation in porphyry copper deposits. Journal of Geochemical Exploration, 102(3): 1–6.

Keywords

References

Agard, P., Monie, P., Gerber, W., Omrani, J., Molinaro, M., Labrousse, L., Vrielynck, B., Meyer, B., Jolivet, L. and Yamato, P., 2006. Transient, syn-obduction exhumation of Zagros blueschists inferred from P–T–deformation–time and kinematic constraints: implications for Neotethyan wedge dynamics. Journal of Geophysical Research: Solid Earth, 111(11): 1-28.
Alirezaei, S., 2009. Stable Isotope Geochemistry. Press University Publication Center, Tehran, 332 pp.
Anderson, R., Graham, C.M., Boyce, A.J. and Fallick, A.E., 2004. Metamorphic and basin fluids in quartz-carbonate-sulphide veins in the SW Scottish Highlands: a stable isotope and fluid inclusion study. Geofluids, 4(2): 169-185.
Asadi, S., Moore, F. and Fattahi, N., 2013. Fluid inclusion and stable isotope constraints on the genesis of the Jian copper deposit, Sanandaj–Sirjan metamorphic zone, Iran. Geofluids, 13(1): 66–81.
Borrak, D.M., Navarrete, J.U. and Kafantaris, F.C.A., 2012. A model for copper isotopic fractionation during weathering and transport. 22th Goldschmidt Conference, Montreal, Canada.
Clayton, R.N., and Mayeda, T.K., 1963. The use of bromine pentafluoride in the extraction of oxygen from oxides and silicates for isotopic analysis. Geochimica et Cosmochimica Acta, 27(1): 43-52.
Cook, N.J., 1994. Post-recrystallisation mobilization phenomena in metamorphosed stratabound sulphide ores .Mineralogical magazine, 57(1): 482-486.
Craig, J.R., Voke, F.M. and Solberg, T.N., 1998. Pyrite: physical and chemical textures. Mineralium Deposita, 34(1): 82-101.
Ehrlich, S., Butler, I., Halicz, L., Rickard, D., Oldroyd, A., and Matthews, A., 2004. Experimental study of the copper isotope fractionation between aqueous Cu (II) and covellite, CuS. Chemical Geology, 209(3): 259-269.
Evans, A.M., 1997. An Introduction to Economic Geology and its Environmental Impact. John Wiley and Sons, London, 403 pp.
Fallick, A.E., Jocelyn, J., and Hamilton, P.J., 1987. Oxygen and hydrogen stable isotope systematics in Brazilian agates, In: R. Rodriguez-Clemente (Editor), Geochemistry of the earth surface and processes of mineral formation. Instituto de Geologia (Consejo Superior de Investigaciones Cientificas-Spanish National Research Council), Madrid, pp. 99-117.
Fattahi, N., 2013. Study of geochemistry and the copper genesis in the Surian complex, Jian (Bavanat, Fars province). M.Sc. Thesis, Shiraz University, Shiraz, Iran, 241 pp.
Haest, M., Muchez, P., Petit, J.C. and Vanhaecke, F., 2009. Cu isotope ratio variations in the Dikulushi Cu-Ag deposit, DRC: of primary origin or induced by supergene reworking? Economic Geology. 104(7): 1055-1064.
Hoefs, J., 2009. Stable Isotope Geochemistry. Springer, Amsterdam, 203 pp.
Liaghat, S. and Jami, M., 1999. The history of the ore microscopy applications. Shiraz University Press, Shiraz, 273 pp.
Liaghat, S. and Taghipour, N., 2000. Genesis of Jian occurrence. 4th Symposium of Geological Society of Iran, University of Tabriz, Tabriz, Iran. (in Persian)
Mathur, R., Ruizi, J.,Titley, S., Liermann, L., Buss, H. and Brantley, S., 2005. Cu isotopic fractionation in the supergene environment with and without bacteria. Geochimica et Cosmochimica Acta, 69 (22): 5233–5246.
Mathur, R., Titley, S., Barra, F., Brantley, S., Wilson, M., Phillips, A., Munizaga, F., Maksaev, V., Vervoort, J. and Hart, G., 2009. Exploration potential of Cu isotope fractionation in porphyry copper deposits. Journal of Geochemical Exploration, 102(3): 1–6.
Matsuhisa, Y., Goldsmith, J.R. and Clayton, R.N., 1979. Oxygen isotopic fractionation in the system quartz-albite-anorthite-water. Geochimica et Cosmochimica Acta, 43(2): 1131-1140.
McClay, K.R. and Ellis, P.G., 1984. Deformation of pyrite. Economic Geology, 79(2): 400-403.
Molinaro, M., Leturmy, P., Guezou, J.C., Frizon de Lamotte, D. and Eshraghi, S.A., 2005. The structure and kinematics of the southeastern Zagros fold–thrust belt, Iran: From thin-skinned to thick-skinned tectonics. Tectonics, 24(3): 1-19.
Moore, F., Asadi, S. and Fattahi, N., 2011. Metamorphic-Hydrothermal fluid evolution based on thermo-barometry and stable isotope studies in Bavanat copper deposit, Sanandaj-Sirjan zone. 15th Symposium of Geological Society of Iran, Tarbiat Moallem University, Tehran, Iran. (in Persian)
Mousivand, F., Rastad, E., Hoshino, K. and Watanabe, M., 2007. The Bavanat Cu-Zn-Ag orebody: first recognition of a Besshi-type VMS deposit in Iran. Neues Jahrbuch für Mineralogie-Abhandlungen, 183(3): 297-315.
Rajabzadeh, M.A. and Esmailei, S., 2012. Petrography and geochemistry of meta-basalts of Jian copper deposit. 15th Symposium of Geological Society of Iran, University of Tehran, Tehran, Iran. (in Persian)
Rollinson, H.R., 1993. Using Geochemical Data: Evaluation, Presentation, Interpretation. Longman Publisher, London, 345 pp.
Sarkarinejad, Kh., 2007. Quantitative finite strain and kinematic flow analyses along the Zagros transpression zone, Iran. Tectonophysics, 442(1): 49-65.
Scott, S.D., Both, R.A. and Kissin S.A., 1971. Sulfide petrology of the Broken Hill region, New South Wales. Economic Geology, 72(8): 1410-1425.
Sheikholeslami, M.R., Pique, A., Mobayen, P., Sabzehei, M., Bellon, H. and Emami, M.H., 2008. Tectono-metamorphic evolution of the Neyriz metamorphic complex, Quri-Kor-e-Sefid area (Sanandaj-Sirjan Zone, SW Iran). Journal of Asian Earth Sciences, 31(4-6): 504–521.
Spry, A., 1969. Metamorphic Textures. Pergamon Press, Oxford, 286 pp.
Stanton, R.L., 1972. Ore Petrology. McGraw-Hill, New York, 713 pp.
Taghipour, N. and Moore, F., 2000. Texture and REE geochemistry in the Jian copper occurrence. Iranian Journal of Crystallography and Mineralogy, 10(2): 51–65.
Walker, E.C., Cuttitta, F., and Senftle, F.E., 1958. Some natural variations in the relative abundance of copper isotopes. Geochimica et cosmochimica acta, 15(3): 183-194.
Zarasvandi, A., Liaghat, S. and Moore, F., 2001. Geochemical prospecting project of copper in the Bavanat area, Fars Province. 5th Symposium of Geological Society of Iran, University of Tehran, Tehran, Iran. (in Persian)
Zhang, L.G., Liu, J.X., Zhou. H.B. and Chen, Z.S., 1989. Oxygen isotope fractionation in the quartz-water-salt system. Economic Geology, 84(6): 1643-1650.
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  • Receive Date: 05 February 2014
  • Accept Date: 21 June 2014

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