The nature of hydrothermal fluids in the Kahang porphyry copper deposit (Northeast of Isfahan) based on mineralography, fluid inclusion and stable isotopic data

Document Type : Research Article

Authors

1 Isfahan

2 Isfahan University of Technology

3 Payame Noor

Abstract

Introduction
The Kahang Cu- Mo deposit is situated approximately 73 Km northeast of Isfahan. Asadi (2007) identified a geological reserve of 40 Mt (proven reserve) grading at 0.53 Cu, 0.02 Mo and estimated reserve of 120 Mt. All the rock types in the region have been subjected to hydrothermal solutions which gave rise to three different alteration facies. The dacite and rhyodacite volcanic rocks and granitic- granodioritic stocks have experienced phyllic alteration. Disseminated and stockwork siliceous veins are the major styles of mineralization in this zone. Intermediate argillitic alteration developed on a part of dacitic and rhyodacitic rocks whereas andesite and basaltic-andesite plus related pyroclastic rocks have been subjected to propyllitic alteration. This paper presents the results of geological and mineralogical studies carried out in the Kahang area. This preliminary information is integrated with additional data on ore mineralogy, fluid inclusions and stable isotopes in view of understanding the genesis of the Cu- Mo deposit and the nature of the fluids involved in ore formation.

Materials and Methods
A total of 18 polished thin sections were prepared at the University of Isfahan for optical study. Fluid inclusions study was carried out on 8 double polished quartz thin sections (stockworks containing ore mineralization from phyllic zone). H – O stable isotope analysis was performed on 4 quartz samples from siliceous stockworks (from phyllic altered zone) and one vein epidote sample (from propyllitic zone). All isotopic analyses were performed at the University of Oregan, Oregan, USA.

Discussion
In the investigated mineralization area, the hypogene zone is characterized by the presence of pyrite, chalcopyrite, bornite and magnetite. Hematite, goethite, jarosite, malachite and azurite are the predominant minerals of supergene zone. The major textures of the primary sulfides are disseminated, vein and veinlet. Pyrite is the most common hypogene sulfide mineral and chalcopyrite is the predominant Cu- sulfide in the Kahang mineralized area. Primary magnetite grains having irregular boundaries formed in association with phyllic –potassic altered zones (Afshooni et al., 2014). Chalcocite and covellite as secondary copper minerals in the enriched supergene zone replaced the chalcopyrite.
Thermometric studies on fluid inclusions conducted on quartz veins was related to the phyllic zone. Almost all studied fluid inclusions were homogenized to the liquid phase. Hydrothermal solutions with salinity over 26% wt equivalent NaCl, comparable with those of the other porphyry deposits (Morales Ruano et al., 2002; Hezarkhani, 2006; Hezarkhani, 2009) were responsible for the formation of the Kahang porphyry copper deposit. Homogenization temperatures of 200-450°C and 500-550°C were obtained from heating- cooling experiments on the two and multi phase fluid inclusions. The presence of gas riched fluid inclusions together with those of liquid riched and multiphase different salinities in the quartz veins as well as the occurrence of hydrothermal breccias are indicative of boiling fluids.

Result
In the Kahang porphyry Cu- deposit, the oxidation zone is characterized by hematite, goethite, jarosite, malachite, and azurite; the supergene zone is identified by chalcocite, chalcopyrite and coevllite; and chalcopyrite, pyrite and magnetite are the mineral assemblage of the hypogene zone. The volcanic as well as the plutonic rocks of the area have been hydrothermally altered which gave rise to the formation of propyllitic, intermediate argillic and mineralized phyllic zones. Fluid inclusion study on quartz veins revealed salinity over 26% wt equivalent NaCl and homogenization temperature of 200-450°C and 500-550°C. The presence of gas riched fluid inclusions together with those of liquid riched and multiphase different salinities in the quartz veins as well as the occurrence of hydrothermal breccias are indicative of boiling event, owing to the pressure reduction in the faulted zones and mineralized hydrothermal breccias and/or increase of hydrostatic pressure compared to the lithostatic pressure. This may be caused by the instability of the copper complex accompanied by precipitation of copper. The decrease of temperature and the diluted mineralized fluids could be the cause of precipitation of copper due to mixing with the meteoric water. Stable isotope study supports the mixing of magmatic and meteoric waters in the peripheral zones of ore deposit (phyllic and propyllitic zones).

Acknowledgements
This paper has benefited from critical comments by Dr. Shamsi pour and Dr. Mackizadeh who are thanked for their interest. Financial support of the University of Isfahan is acknowledged.

References
Afshooni, S.Z., Esmaeily, D. and Asadi Haroni, H., 2014. Stable isotopes (S, H, O) study In phyllic and potassic- phyllic alteration zones of the Kahang porphyry copper- Molybdenum deposit (Northeast of Isfahan). Journal of Advanced Applied Geology, 1(7): 64-73. (in Persian)
Asadi, H., 2007. Detailed exploration in Kahang porphyry Cu- Mo index. Dorsa pardazeh company, Isfahan, Report 3, 114 pp. (in Persian)
Hezarkhani, A., 2006. Hydrothermal evolution of the Sar-Cheshmeh porphyry Cu-Mo deposit, Iran: Evidence from fluid inclusions. Journal of Asian Earth Sciences, 28(4-6): 409-422.
Hezarkhani, A., 2009. Hydrothermal fluid geochemistry at the Chah-Firuzeh porphyry copper deposit, Iran: Evidence from fluid inclusions. Journal of Geochemical Exploration, 101(3): 254-264.
Morales Ruano, S., Both, R.A. and Golding, S.D., 2002. A fluid inclusion and stable isotope study of the Moonta copper-gold deposits, South Australia: evidence for fluid immiscibility in a magmatic hydrothermal system. Chemical Geology, 192(3-4): 211-226.

Keywords

References

Afshooni, S.Z., Esmaeily, D. and Asadi Haroni, H., 2014. Stable isotopes (S, H, O) study In phyllic and potassic- phyllic alteration zones of the Kahang porphyry copper- Molybdenum deposit (Northeast of Isfahan). Journal of Advanced Applied Geology, 1(7): 64-73. (in Persian)
Alavi, M., 1994. Tectonic of the Zagros orogenic belt of Iran, new data and interpretations. Tectonophysics, 229(3-4): 211-238.
Alpers, C.N. and Brimhall, G.H., 1989. Paleohyrologic evolution and geochemical dynamics of cumulative supergene metal enrichment at La Escondida, Atacama Desert, Northern Chile. Economic Geology, 84(2): 229-255.
Amidi, S.M., 1975. Contribution a'letude stratigraphique, petrologique et petrographique des roches magmatiques de la region Natanz-Nain-Surk (Iran central). Ph.D. Thesis, University of Grenoble France, Grenoble, France, 316 pp.
Asadi, H., 2007. Detailed exploration in Kahang porphyry Cu- Mo index. Dorsa pardazeh company, Isfahan, Report 3, 114 pp (in Persian).
Asghari, O. and Hezarkhani, A., 2010. Investigations of alteration zones based on fluid inclusion microthermometry at Sungun porphyry copper deposit, NW Iran. Bulletin of The Mineral Research and Exploration, 140(4): 19-34.
Ayati, F., 2010. Neogene magmatism and their related hydrothermal alterations in NE of Arak. Ph.D. Thesis, University of Isfahan, Isfahan, Iran, 340 pp (in Persian with English abstract).
Ayati, F., Asadi Harouni, H., Bagheri, H. and Mansouri Isfahani, M., 2012. Application of mineralography and fluid inclusion data to determine the formation conditions of porphyry copper deposit, NE Arak. Petrology, 3(12): 15-32 (in Persian with English abstract).
Calagari, A.A., 2003. 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(7): 767-780.
Calagari, A.A., 2004. Fluid inclusion studies in quartz veinlets in the porphyry copper deposit at Sungun, East-Azarbaidjan, Iran. Journal of Asian Earth Sciences, 23(2): 179-189.
Clayton, R.N., O΄Neil, J.R. and Mayeda, T.K., 1972. Oxygen isotope exchange between quartz and water. Journal of Geophysics Research, 77 (17): 3057-3067.
Cunningham, C., 1978. Pressure gradients and boiling as mechanisms for localizing ore in porphyry system. Journal of Research of the U.S. Geological Survey, 6(4): 745-754.
Farahani Farmahini, M., 2008. Geology, geochemistry and mineralogy investigations of Kahang index. Ph.D. Thesis, Islamic Azad University Science and Research Branch, Tehran, Iran, 200 pp (in Persian with English abstract).
Forster, H., 1974. Continental drift in Iran in relation to the Afar structures. International Symposium on the Afar Region and Related Rift Problems, Bad Bergzabern, Germany.
Guilbert, J.M. and Park, Jr.C.F., 1997. The geology of ore deposits. Freeman and company, New York, 985 pp.
Hatami, Sh., 2008. Petrology of Kahang granitoids and volcanic rocks with emphasis on mineralization and alteration zones. M.Sc. Thesis, Islamic Azad University Khorasgan Branch, Isfahan, Iran, 110 pp (in Persian with English abstract).
Hezarkhani, A., 2006. Hydrothermal evolution of the Sar-Cheshmeh porphyry Cu-Mo deposit, Iran: Evidence from fluid inclusions. Journal of Asian Earth Sciences, 28(4-6): 409-422.
Hezarkhani, A., 2009. Hydrothermal fluid geochemistry at the Chah-Firuzeh porphyry copper deposit, Iran: Evidence from fluid inclusions. Journal of Geochemical Exploration, 101(3): 254-264.
Karimpour, M.H. and Saadat, S., 2002. Applicable economic geology. Mashhad University Publications, Mashhad, 535 pp (in Persian).
Kertz, R., 1983. Symbols for rock-forming minerals. American Mineralogist, 68: 227-279.
Komeili, S.S., 2010. Petrology and geochemistry of the Kahang porphyry Cu- Mo index and related hydrothermal alteration zones. M.Sc. Thesis, University of Isfahan, Isfahan, Iran, 189 pp (in Persian with English abstract).
Mehrpartou, M. and torkiyan, M., 1993. Research of fluid inclusions in the Sungun porphyry copper- Molybdenum deposit (west of Ahar- Azarbayjan-e gharbi). Geosciences, 3(10): 2-27 (in Persian).
Mehvari, R., Shamsipour, R., Bagheri, H., Noghreyan, M. and Mackizadeh M.A., 2010. Mineralogical and fluid inclusion studies in the Kalchueh copper- gold deposit, Earth of Isfahan. Journal of Economic Geology, 1(1): 47-55 (in Persian with English abstract).
Morales Ruano, S., Both, R.A. and Golding, S.D., 2002. A fluid inclusion and stable isotope study of the Moonta copper-gold deposits, South Australia: evidence for fluid immiscibility in a magmatic hydrothermal system. Chemical Geology, 192(3-4): 211-226.
Radfar, J. and Kohansal, R., 2002. Geological map of Iran (Kuhpayeh), scale 1:100,000. Geological Survey and Mineral Exploration of Iran.
Roedder, E., 1972. Composition of fluid inclusions. In: M. Fleischer, (Editor), Data of geochemistry. United States Government printing office, Washington, pp. i-JJ189.
Shahabpour, J., 1994. Post-mineralization breccia dike from the Sar-Cheshmeh porphyry copper deposit, Kerman, Iran. Exploration and Mining Geology, 3(1): 39-43.
Shahabpour, J., 2000. Some sulfide- silicate assemblages from the Sar-Cheshmeh porphyry copper deposit, Kerman, Iran. Journal of Sciences, Islamic Republic of Iran, 11(1): 39-48.
Sheppard, S.M.F., 1977. Identification of the origin of ore-forming solutions by the use of stable isotopes, in volcanic processes, in ore genesis. Geological Society of London, 7(1): 25-41.
Sheppard, S.M.F., 1986. Characterization and isotopic variations in natural waters. Reviews in Mineralogy, 16(1): 165–183.
Takenouchi, S., 1980. Preliminary studies of fluid inclusions of the Santo Tomas II (Philex) and Tapian (Marcopper) porphyry copper deposits in the philippines. Mining Geology Special Issue, 8(9-10): 141-150.
Ulrich, T., Günther, D. and Heinrich, C.A., 2002. The evolution of a porphyry Cu-Au deposit, based on LA-ICP-MS analysis of fluid inclusions: Bajo de la Alumbrera, Argentina. Economic Geology, 97(8): 1889-1920.
Van den Kerkhof, A.M. and Hein, U.F., 2001. Fluid inclusion petrography. Lithos, 55(1-4): 27-47.
Vink, B.W., 1986. Stability relations of malachite and azurite. Mineralogical Magazine. 50(355): 41-47.
Walshe, J.L. and Hobbs, B.E., 1999. Hydrothermal systems, giant ore deposits and a new paradigm for predictive mineral exploration. CSIRO Exploration and Mining, North Ryde (Australia), 133 pp.
Wilkinson, J.J., 2001. Fluid inclusions in hydrothermal ore deposits. Lithos, 55 (1-4) 229-272.
Zhong, J., Chen, Y.J., Pirajno, F., Chen, J., Li, J., Qi, J.P. and Li, N., 2014. Geology, geochronology, fluid inclusion and H-O isotope geochemistry of the Louboling Porphyry Cu-Mo deposit, Zijinshan Orefield, Fujian Province, China. Ore Geology Reviews, 57(1): 61-77.
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 12 July 2014
  • Accept Date: 08 June 2015

Share

How to cite

Statistics