Systematic sulfur stable isotope and fluid inclusion studies on veinlet groups in the Sarcheshmeh porphyry copper deposit: based on new data

Document Type : Research Article

Authors

Bu-Ali Sina

Abstract

Mineralization occurred by intrusion of granodioritic stock of middle Miocene in volcano–sedimenrary rocks in Sarcheshmeh of early Tertiary age. This research is based on samples of new drilled boreholes and benches of 2500m elevation. Based on mineralogy and crosscutting relationships, at least four groups of veinlets pertaining to four stages of mineralization were recognized. Sulfur isotope studies in the Sarcheshmeh porphyry copper deposit were conducted on pyrite, chalcopyrite, molybdenite and anhydrites of four groups of veinlets. The δ34S values in the sulfides and sulfates range from -2.2 to 1.27‰ and from 10.2 to 14.5 ‰, respectively. The average δ34S value in the sulfides is 1‰ and that for the sulfates is about 13‰. Considering these results, it can be concluded that the sulfides made up of a fluid that its sulfur has a magmatic origin. Also, fluid inclusions of different veinlet groups were studied, showing high temperature, high salinity and the occurrence of boiling in the mineralizing fluids. Moreover, these studies indicate presence of three types of fluids including magmatic, meteoritic and mixture of these two fluids in alteration and mineralizion processes.

Keywords

References

[1] صالحی ر.، "بررسی ژئوشیمیایی زون های آلتره در معدن مس سرچشمه و تأثیر معدن کاری در پراکنش و انحلال پذیری فلزات سنگین"، پایان نامه کارشناسی ارشد، دانشگاه اصفهان (1383) 180 ص.
[2] امین زاده ب.، "مطالعه کانی شناسی و ژئوشیمی سیالات درگیر در ارتباط با کانسارسازی مولیبدن در معدن مس سرچشمه و کاربرد آن در بازیابی موثر مولیبدن"، پایان نامه
کارشناسی ارشد زمین‌شناسی اقتصادی، دانشگاه شهید باهنر کرمان (1385) 112ص.
[3] صفاری م. م.، "بررسی توزیع و تمرکز عناصر کمیاب و گرانبها و عوامل کنترل کننده آنها در کانسار مس پورفیری سرچشمه (کرمان)"، پایان نامه کارشناسی ارشد زمین شناسی اقتصادی، دانشگاه شهید بهشتی (1377) 100ص.
[4] Hezarkhani A., "Hydrothermal evolutions at the Sar-Cheshmeh porphyry Cu–Mo deposit, Iran: evidence from fluid inclusions", Journal of Asian Earth Sciences 28 (2006) 408–422.
[5] Forster H., "Mesozoic-Cenozoic metallogenesis in Iran", Jnl. Geology. Soc. London 135 (1978) 443-455.
[6] Etminan H., "Le porphyry cuprifere de Sarcheshmeh Rol des phases fluide les mecanismes alteration et de mineralization", Iran Geology. Survey (1977) 242.
[7] Shahabpour J., "Aspects of alteration and mineralization at the Sarcheshmeh copper - molybdenum deposit. Kerman, Iran", Unpub Ph.D. thesis., Leeds University (1982) 342.
[8] Emami H., "Geology of the Sar-Cheshmeh Copper Deposit: Internal Reports", Sar-Cheshmeh Copper Company (1992).
[9] Waterman G. C., Hamilton R., "The sarcheshmeh porphyry copper deposit", Economic Geology 70 (1975) 568-576.
[10] Bazin D., Hubner H., "La region cuprifere a gisements porphyriques de Kerman (Iran) ",Mineral Deposita 4 (1969) 200-211.
[11] Bodnar R. J., "Fluid-inclusion evidence for a magmaticsource for metals in porphyry copper deposits", In: Thompson,J.F.H. _Ed.., Magmas, Fluids, and Ore Deposits. Mineral. Assoc. Can., Short Course Series 23 (1995) 139-152.
[12] Wilkinson J. J., "Fluid inclusions in hydrothermal ore deposits", Lithos 55 (2001) 229-272.
[13] Roedder E., "Fluid inclusions. Mineralogical Society of America", Reviews in Mineralogy 12 (1984) 644.
[14] Bodnar R. J., Vityk M.O., "Interpretation of micro thermometric data for H2o-NaCl fluid inclusions", In fluid inclusions in Minerals, Methods and Applications, B.De Vivo and M.L. Frezzotti, eds., pub, by Virginia Tech, Blacksburg, Va (1994) 117-130.
[15] Chou I. M., "Phase relations in the system NaCl–KCl–H2O. III: solubilities of halite in vapour-saturated liquids above 445 8C and redetermination of phase equilibrium properties in the system NaCl–H2O to 1000 8C and 1500 bars", Geochimica et Cosmochimica Acta 51 (1987) 1965-1975.
[16] Kerkhof A. M. V., Hein U. F., "Fluid inclusion petrography", Lithos 55 (2001) 27-47.
[17] Borinseko A. S., "Study of the salt compositionof solution in gas-liquid inclusions in mineral by the cryometric method", Soviet Geol. and Geographys 18 (1977) 11-19.
[18] Nast H. J., Williams-Jones A. E., "The role of water–rock interaction and fluid evolution in forming the porphyry-related Sisson Brook W–Cu–Mo deposit, New Brunswick", Economic Geology 86 (1991) 302-317.
[19] Roedder E., Bodnar R. J., "Geologic pressure determinations from fluid inclusion studies", Earth Planet Science 8 (1980) 263-310.
[20] Shepherd T., Rankin A. H., ALderton D. H. M., "A Practical Guide to Fluid Inclusion Studies", Blackie (1985) 239.
[21] Ohmoto H., "Systematics of sulfur and carbon isotopes in hydrothermal ore deposits", Economic Geology 67 (1972) 551-579.
[22] Rollinson H. R., "Using geochemical data", Longman Scientific and Technical (1993) 384.
[23] Chaussidon M., Lorand J. P., "Sulphur isotope composition spinel lerzolite massifs from Ariege (N.E. Pyrenees. France): An ion microprobe study", Geochimical et Cosmochimical 54 (1990) 2835-2846.
[24] Hoefs J., "Stable isotope geochemistry", Springer Verlag, Berlin, 5th edition (2004) 244.
[25] Calagari A. A., "Stable isotope (S, O, H and C) studies of the phyllic and potassic–phyllic alteration zones of the porphyry copper deposit at Sungun, East Azarbaidjan, Iran", Journal of Asian Earth Sciences 21 (2003) 767-780.
[26] Ohmoto H., "Stable isotope geochemistry of ore deposits", Mineralogical Society of America 16 (1986) 491-570.
[27] Ohmoto H., Rye R. O., "Isotopes of sulfur and carbon: in H.L. Barnes ed", Geochemistry of Hydrothermal Ore Deposits, Second Edition: John Wiley & Sons (1979) 509-567.
[28] Ohmoto H., Lasaga A. C., "Kinetics of reactions between aqueous sulphates and sulphides in hydrothermal systems", Geochimical et Cosmochimical 46 (1982) 1727-1745.
[29] Field C. W., Gustafson L. B., "Sulfur isotopes in the porphyry deposits at El Salvador, Chile", Econmic Geology 71 (1976) 1533-1548.
[30] Hezarkhani A., Williams-Jones A. E., Gammons C. H., "Factors controlling copper solubility and chalcopyrite deposition in the Sungun porphyry copper deposit, Iran", Mineralium Deposita 34 (1999) 770-783.
[31] Burnham C. W., "Physiochemical constraints on porphyry mineralization", In: Dickenson, W.R., Payne, W.D. (Eds.), Relations of Tectonics to OreDeposits in the Southern Cordillera,. Arizona Geological SocietyDigest, Arizona 14 (1981) 71-77.
[32] Dimitrijevic M. D., Dimitrijevic M. N., Djordjevic M., Vulovic D., "Geological Survey of Iran, 1:100,000 series", sheet 7149, Pariz, (1971).
[33] Li Y. B., Liu J. M.,"Calculation of sulfur isotope fractionation in sulfides", Geochimica et Cosmochimica Acta 70 (2006) 1789-1795.
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 05 June 2012
  • Accept Date: 30 October 2012

Share

How to cite

Statistics