Investigation of petrography, mineralogy and alteration of northern part of the Chahfiruzeh porphyry copper deposit, northwest of Shar-e-Babak, Kerman

Document Type : Research Article

Authors

University of Sistan and Baluchestan

Abstract

Introduction
The Chahfiruzeh porphyry copper deposit is located at 35 Km northwest of Shar-e-Babak in Dehaj–Sarduieh part of the Urumieh- Dokhtar magmatic arc (UDMA). The world class porphyry Cu deposits, such as Sarcheshmeh, Meiduk, Sungun and several other Cu-porphyry in the UDMA have been  numerously studied, for example: Boomeri, et al., (2009, 2010), and Asadi et al., (2014). The Chahfiruzeh Cu porphyry is divided into two parts of the southern and northern deposits. The southern deposit was studied by Hezarkhani (2006), and Sheikhzadeh et al., (2011). This paper studies the northern part to distinguish mineralized rock units, alteration types, mineralization style, ore mineralogy and geochemical characteristics.
 
Geology
Geology of the northern part of the Chahfiruzeh area consists of upper Cretaceous-Eocene andesitic lava, pyroclastic and volcanoclastic rocks that have been intruded by Oligo-Miocene intermediate stocks and dikes (Dimitrijevic, 1973).  Neogene rocks in the area are mainly alkali basalt to dacitic domes and Quaternary alluvium deposits.
 
Method and material
During the field studies more than 100 samples were taken from the boreholes and outcrops.  Among them 25 thin sections and 39 polished sections were studied by microscopic methods, 6 samples from the alteration zones, 8 samples from the less altered rocks and 25 samples from the mineralized rocks were examined and analyzed by XRD, XRF and ICP-OES, respectively. The analyses and XRD data are presented in Tables 1, 2 and 4.
 
Result and discussion
Petrography
The igneous rocks in the northern part occur as extrusive and intrusive. The extrusive rocks are dacite and andesite and intrusive rocks are diorite, granodiorite and quartzdiorite. They are porphyry in texture and high-K calc-alkaline in magmatic series. The main mineral in all rocks is plagioclase that has variable size, shape and texture. K-feldespar, amphibole, biotite and quartz are other primary minerals in the study rocks. Biotite, quartz, and K-feldspar occur also as secondary minerals that are associated with chlorite, sericite, clays minerals and sulfide and oxide minerals.
 
Mineralization
Mineralization can be usually divided into the two hypogene and supergen types. The hypogene mineralization occurs mainly as silicic veinlets and disseminated in the intrusive porphyries and volcanic rocks. The silicic veins are in eleven types as follows: 1) quartz + chlorite + pyrite, 2) quartz + chlorite , 3) quartz + pyrite , 4) quartz , 5) chlorite , 6) pyrite + chalcopyrite + quartz , 7) quartz + magnetite , 8) pyrite , 9), chalcopyrite , 10) quartz + chalcopyrite + bornite, 11) molybdenite.  The hypogene sulfides are pyrite, chalcopyrite, bornite and molybdenite that are associated with magnetite, hematite and ilmenite.  The pyrites and chalcopyrites occur in all parts of the mineralized area from the surface to the depth while molybdenites and bornites occur only in the deep depths. The supergene mineralization occurs as small outcrops of iron oxide and hydroxide, copper carbonate and clay minerals.
 
Alteration
The alteration zones in the mineralized area are potassic, propylitic, phyllic and argillic. The main alteration is potassic that is characterized by biotite, sericite and chlorite and numerous sulfide-bearing silicic veinlets with or without orthoclase and magnetite.  The orthoclase is probably present as anhedral in some parts and around the plagioclase. The hydrothermal biotites are fine and thin in shape and occur in groundmass. Magmatic biotites are also present as euhedral to subhedral grains. The propylitic alteration observes only in the surface as an outer zone and characterized mainly by chlorite and epidote. Calcite and clay minerals are other minerals of this zone while sulfides are rare. The phyllic alteration zone is characterized by a higher proportion of sericite, quartz veins and pyrite than the potassic alteration in the marginal parts of the mineralized area. The argillic alteration zone occurs locally in shallow depths. Based on XRD analyses, each one of the clay minerals such as kaolinite, montmorillonite, illite and dickite, are dominant in some samples.
The alteration map of the northern part is presented in Fig.15 for two depths of 10 and 400 meters.  The potassic alteration is the main alteration type in both levels. In level 10, the inner potassic alteration is surrounded by phyllic and outer propylitic alteration, while in level 400, the inner potassic alteration is only associated with the local phyllic alteration. Distribution of copper and molybdenum in different boreholes indicate that mineralization has occurred mainly in the potassic and phyllic alteration zones (Fig. 16). The copper shows similar contents from shallow to deeper depths while Mo contents are higher in the depths of more than 500 meters (Fig. 16).
The following features show that the northern part of Chahfiruzeh ore deposit is a porphyry Cu-type ore deposit: style, grade, size and shape of the mineralization, alteration types, associated calc-alkaline intrusive porphyries and the tectonic setting.
 
References
Asadi, S., Moore, F. and Zarasvandi, A., 2014. Discriminating productive and barren porphyry copper deposits in the southeastern part of the central Iranian volcano-plutonic belt, Kerman region, Iran: A review.  Earth Science Reviews, 138(1):25–46.
Boomeri, M., Nakashima, K. and Lentz, D.R., 2009. The Miduk porphyry Cu deposit, Kerman, Iran: a geochemical analysis of the potassic zone including halogen element systematic related to Cu mineralization processes. Journal of Geochemical Exploration, 103(1): 17–29.
Boomeri, M., Nakashima, K. and Lentz, D.R., 2010. The Sarcheshmeh porphyry copper deposit, Kerman, Iran: a mineralogical analysis of the igneous rocks and alteration zones including halogen element systematics related to Cu mineralization processes. Ore Geology Reviews, 38(4): 367–381.
Dimitrijevic, M.D., 1973. Geology of Kerman region. Geology survey, Tehran, Iran, Report YU/53, 334 pp.
Hezarkhani, A., 2006. Petrology of the intrusive rocks within the Sungun porphyry copper deposit, Azerbaijan, Iran. Jurnal of Asian Earth Sciences, 27(3): 326–340.
Sheikhzadeh, A., Mokhtari, A., Fatheianpur, N. and Sahebazamani, N., 2011. Isolation of high-grade copper zone using exploratory data analysis on a case study, Chahfirozeh deposit. 29th Symposium of Earth Sciences, Gological Survey and Mineral Exploration, Tehran, Iran. (in Persian with English abstract)

Keywords

References

Adeli Sarcheshmeh, A., Karimi, M., Bahroudi, E. and Elyasi, G., 2009. Determination of boreholes location by GIS in Chafiruzeh. Sciences Magazine of University of Tehran, 35(2):85–97. (in Persian)
Arancibia, O.N. and Clark, A.H., 1996. Early magnetite–amphibole–plagioclase alteration-mineralization in the Island copper porphyry copper–gold–molybdenum deposit, British Columbia. Economic Geology, 91(2): 402–438.
Asadi, S., Moore, F. and Zarasvandi, A., 2014. Discriminating productive and barren porphyry copper deposits in the southeastern part of the central Iranian volcano-plutonic belt, Kerman region, Iran: A review. Earth Science Reviews, 138(1):25–46.
Barzegar, H., 2007. Geology, petrology, and geochemical characteristics of alteration zones within the Seridune prospect, Kerman, Iran. Ph.D. thesis, Aachen University, Aachen, Germany, 180 pp.
Bazin, D. and Hubner, H., 1969. Copper deposits in Iran. Geology Survey, Tehran, Iran, Report, 13, 232 pp.
Boomeri, M., Nakashima, K. and Lentz, D.R., 2009. The Miduk porphyry Cu deposit, Kerman, Iran: a geochemical analysis of the potassic zone including halogen element systematic related to Cu mineralization processes. Journal of Geochemical Exploration, 103(1): 17–29.
Boomeri, M., Nakashima, K. and Lentz, D.R., 2010. The Sarcheshmeh porphyry copper deposit, Kerman, Iran: a mineralogical analysis of the igneous rocks and alteration zones including halogen element systematics related to Cu mineralization processes. Ore Geology Reviews, 38(4): 367–381.
Cooke, D.R., Hollings, P. and Walshe, J.L., 2005. Giant porphyry deposits: characteristics, distribution, and tectonic controls. Economic Geology, 100(5): 801–818.
Cox, K.G., Bell, J.D. and Pankhurst, R.J., 1979. The Interpretation of Igneous Rocks. Allen and Unwin, London, 450 pp.
Dimitrijevic, M.D., 1973. Geology of Kerman region. Geology survey, Tehran, Iran, Report YU/53, 334 pp.
Dimitrijevic, M.D., Dimitrijevic, M.N., Djordjevic, M. and Djokovic, I., 1971. Geological map of Shar-e-Babak II (1:100000 scale). Geological Survey, Tehran, Iran.
Einali, M., Alirezaei, S. and Zaccarini, F., 2014. Chemistry of magmatic and alteration minerals in the Chahfiruzeh porphyry copper deposit, south Iran: implications for the evolution of the magmas and physicochemical conditions of the ore fluids. Turkish Journal of Earth Sciences, 23(2): 147–165.
Förster, H., 1978. Mesozoic and Cenozoic metallogenesis in Iran. Journal of the Geological Society, 135(4): 443–455.
Golestani, M., Karimpour, M.H., Malekzadeh Shafaroudi, A. and Haidarian Shahri, M.R., 2017. Characterization of fluid inclusions and sulfur isotopes in the Ijo porphyry copper deposit, northwest of Share-e-Babak. Journal of Economic Geology, 9(1): 25–55. (in Persian with English abstract)
Guilbert, J.M. and Park, J.R., 1997. The geology of ore deposits. Freeman and Company, New York, 985 pp.
Gustafson, L.B. and Hunt, J.P., 1975. The porphyry copper deposit at El Salvador, Chile. Economic Geology, 70(5): 857–912.
Harris, A.C., Kamenetsky, V.S., White, N.C., van Achterbergh, E., and Ryan, C.G., 2003. Melt inclusions in veins: Linking magmas and porphyry Cu deposits. Science, 302(5653): 2109–2111.
Hassanzadeh, J., 1993. Metallogenic and tectonomagmatic events in the SE sector of the Cenozoic active continental margin of Iran (Shahre Babak area, Kerman province). Ph.D. thesis, University of California, Los Angeles, America, 204 pp.
Hedenquist, J.W. and Richards, J.P., 1998. The influence of geochemical techniques on the development of genetic models for porphyry copper deposits. Reviews in Economic Geology, 10(1): 235–256.
Hezarkhani, A., 2006. Petrology of the intrusive rocks within the Sungun porphyry copper deposit, Azerbaijan, Iran. Jurnal of Asian Earth Sciences, 27(3): 326–340.
Hezarkhani, A., 2009. Hydrothermal fluid geochemistry at the Chah-Firozeh porphyry copper deposit, Iran: evidence from fluid inclusion, Jornal of Geochemical Exploration, 101(3): 254–264.
Hezarkhani, A. and William-Jones, A.E., 1998. Controls of alteration and mineralization in the Sungun porphyry copper deposit, Iran: evidence from fluid inclusions and stable isotopes. Economic Geology, 93(5): 651–670.
Jonkovic, S., 1977. The copper deposits and geotectonic setting of Tethytan Eurasian metallogenic belt. Mineralium Deposita, 12(1): 37–47.
Kazemi-Mehrnia, A., 2010. Characteristics of leached capping and evolution of supergene enrichment of Northwest Kerman belt copper-molybdenum porphyry deposits. Ph.D. thesis, University of Shahid Beheshti, Tehran, Iran, 310 pp.
Kesler, S.E., 1973. Copper, molybdenum and gold abundances in porphyry copper deposits. Economic Geology, 68(1): 106–112.
Kerrich, R., Goldfarb, R., Groves, D., Garwin, S. and Jia, Y., 2000.The characteristics, origins, and geodynamic settings of supergiant gold metallogenic provinces. Science in China Series D (Earth Sciences), 43(1 supplement): 1–68.
Lowell, J.D. and Guilbert, J.M., 1970. Lateral and vertical alteration-mineralization zoning in porphyry ore deposits. Economic Geology, 65(4): 373–408.
Maanijou, M., Mostaghimi, M., Abdollahy Riseh, M. and Sepahi Gerow, A.A., 2012. Systematic sulfur stable isotope and fluid inclusion studies on veinlet groups in the Sarcheshmeh porphyry copper deposit: based on new data. Journal of Economic Geology, 4(2): 217–239. (in Persian with English abstract)
Mohammadzadeh, Z., 2009. Geology, alteration and copper mineralization in Chahfiruzeh area, Shahr Babak, Kerman. M.Sc. thesis, Shahid Beheshti University, Tehran, Iran, 200 pp. (in Persian)
Myers, G.L., 1994. Geology of the copper Canyon-Fortitude skarn system, Battle Mountain, Nevada. Ph.D. thesis, Washington State University, Pullman, Washington, America, 393 pp.
Peccerillo, A. and Taylor, S.R., 1976. Geochemistry of Eocene calc-alkaline volcanic rocks from the Kastamonu area, Northern Turkey. Contributions to Mineralogy and Petrology, 58(1): 63–81.
Pouramini, S., 2008. Investigation of petrography, geochemistry and petrogenesis of Kahtokerha rocks and its relationship with mineralization. M.Sc. thesis, Shahid Bahonar University, Kerman, Iran, 190 pp. (in Persian)
Richards, J.P., 2003.Tectono-magmatic precursors for porphyry Cu-(Mo-Au) deposit formation. Economic Geology, 98(8): 1515–1533.
Shafiei, B., 2008. Metallogenic model of Kerman porphyry copper belt and its exploratory approaches. Ph.D. thesis, Shahed Bahonar University, Kerman, Iran, 257 pp. (in Persian)
Shafiei, B. 2010. Lead isotope signatures of the igneous rocks and porphyry copper deposits from the Kerman Cenozoic magmatic arc (SE Iran), and their magmatic–metallogenetic implications. Ore Geology Reviews, 38(1–2): 27–36.
Shafiei, B. and Shahabpour, J., 2008. Gold distribution in porphyry copper deposits of Kerman region, southeastern Iran. Journal of Sciences, Islamic Republic of Iran, 19(3): 247–260.
Shahabpour, J., 1982. Aspects of alteration and mineralization at the Sar-Cheshmeh copper–molybdenum deposit, Kerman, Iran. Ph.D. Thesis, Leeds University, U.K., 342 pp.
Shahabpour, J., 1999. The role of deep structures in the distribution of some major ore deposits in Iran, NE of the Zagros thrust zone. Journal of Geodynamics, 28(2–3): 237–250.
Sheikhzadeh, A., Mokhtari, A., Fatheianpur, N. and Sahebazamani, N., 2011. Isolation of high-grade copper zone using exploratory data analysis on a case study, Chahfirozeh deposit. 29th Symposium of Earth Sciences, Gological Survey and Mineral Exploration, Tehran, Iran. (in Persian with English abstract)
Sillitoe, R.H., 2010. Porphyry-copper systems. Economic Geology, 105(1): 3–41.
Taghipour, N., Aftabi, A. and Mathur, R., 2008. Geology and Re–Os geochronology of mineralization of the Miduk porphyry copper deposit. Resource Geology, 58(2): 143–160.
Sun, W., Huang, R.F., Li, H., Hu, H.B., Zhang, C.C., Sun, S.J., Zhang, L.P., Ding, X., Li, C.Y., Zartman, R. E. and Ling, M.X., 2015. Porphyry deposits and oxidized magmas. Ore Geology Reviews, 65(1) : 97-131.
Waterman, G.C. and Hamilton, R.L., 1975. The Sar–Cheshmeh porphyry copper deposit. Economic Geology, 70(3): 568–576.
Whitney, D.L. and Evans, B.W., 2010. Abbreviations for names of rock forming minerals. American Mineralogist, 95(1): 185–187.
Wilkinson, J.J., 2013. Triggers for the formation of porphyry ore deposits in magmatic arcs. Nature Geoscience, 6(77): 917–925.
Yousefi, S.J. and Moradian, A., 2012. Cu-Au mineralization pattern in Chahargonbad (Sirjan) using mineralogy, alteration, geochemical and statistical studies. Journal of Economic Geology, 4(1): 135-153. (in Persian with English abstract)
Zarasvandi, A., Liaghat, S. and Zentilli, M., 2005. Geology of the Darreh-Zerreshk and Ali-Abad porphyry copper deposits, Central Iran. International Geology Review, 47(6): 620–646.
Zeinadini, Z., 2013. Cu and Mo mineralization and geochemistry of north part of Chafirozeh porphyry copper deposit. M.Sc. thesis, University of Sistan and Baluchestan, Zahedan, Iran, 112 pp. (in Persian with English abstract)
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  • Receive Date: 16 March 2017
  • Accept Date: 11 December 2017

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