Mineralogy and skarnification processes at the Avan Cu-Fe Skarn, northeast of Kharvana, NW Iran

Document Type : Research Article

Authors

1 Zanjan

2 Tarbiat Modares

Abstract

Introduction
The Avan Cu-Fe skarn is located at the southern margin of Qaradagh batholith, about 60 km north of Tabriz. The Skarn-type metasomatic alteration is the result of Qaradagh batholith intrusion into the Upper Cretaceous impure carbonates. The studied area belongs to the Central Iranian structural zone. In regional scale, the studied area is a part of the Zangezour mineralization zone in the Lesser Caucasus. Several studies (Karimzadeh Somarin and Moayed, 2002; Calagari and Hosseinzadeh, 2005; Mokhtari, 2008; Baghban Asgharinezhad, 2012; Mokhtari, 2012) including master’s theses and research programs have been done on some skarns in the Azarbaijan area considering their petrologic and mineralization aspects. However, before this study, the Avan skarn aureole has not been studied in detail. In this paper, various geological aspects of the Avan skarn including mineralogy, bi-metasomatic alteration, metasomatism and mineralization during the progressive and retrograde stages of the skarnification processes have been studied in detail.

Research Method
This research consists of field and laboratory studies. Field studies include preparation of the geological map, identifying the relationship between the intrusion and the skarn aureole, identifying the relationship between different parts of the skarn zone and also collecting samples for laboratory studies. Laboratory studies include petrography, mineralography and microprobe studies. Cameca SX100 Microprobe belonging to Geological Survey of the Czech Republic was used in order to determine the chemical composition of the calc-silicate minerals such as pyroxene and garnet in garnet skarn and pyroxene- garnet skarn sub-zones.

Discussion and conclusion
Qaradagh batholith is composed of discrete acid to mafic phases including gabbro, diorite, quartz diorite, quartz monzonite, quartz monzodiorite, tonalite, granodiorite, monzogranite and granite porphyry which is dominated by granodiorite-quartz monzonite. Granitoids of this batholith are metaluminus, high K calc-alkaline I-type granite (Mokhtari, 2008). The Avan Cu-Fe skarn is related to the intrusion of granodioritic-quartz monzonitic part of the Qaradagh batholith into the Upper Cretaceous flysch- type rocks consisting of biomicrite, clay limestone, marl, siltstone and mudstone.
The Avan skarn consists of three zones of endoskarn, exoskarn and marble. The main Cu-Fe mineralized zone is related to the exoskarn zone, which has 600 meters of length and 50 meters of thickness, respectively. The Exoskarn zone consists of garnet skarn, pyroxene-garnet skarn and ore skarn sub-zones. Garnet, belonging to ugrandite series (Ad53-89) with more than 50 percentage in volume, is the most important anhydrous calc-silicate mineral in the garnet skarn and the pyroxene-garnet skarn sub-zones. Some of the garnet crystals are zoned and their chemical composition changes toward the rim to almost pure andradite (Ad99). Clinopyroxene which has diopsidic composition (Di75-96), is another anhydrous calc-silicate mineral in the exoskarn zone with an abundance that reaches up to 50 percent in volume in pyroxene-garnet skarn sub-zone.
The ore skarn sub-zone is located toward the outer part of the exoskarn zone and close to the border of the marble zone. The abundance of ore minerals in this sub-zone reaches up to 50 percentage in volume and includes magnetite, hematite, pyrite, chalcopyrite, bornite, malachite and goethite among which pyrite is the most abundant. In this sub-zone, anhydrous calc-silicate minerals of garnet and clinopyroxene have undergone intensive alteration and are replaced with hydrous calc-silicate (epidote and tremolite- actinolite), oxide (magnetite and hematite) and sulfide (pyrite, chalcopyrite and bornite) minerals.
Based on the textural and mineralogical studies, the skarnification processes in the studied area can be categorized into two main stages: 1) prograde and 2) retrograde. During the prograde stage, the heat flow of the granitoid has caused isochemical metamorphism and changing more pure limestones to marble and marlly limestones to skarnoid (metamorphism and bi-metasomatism). The high temperature magmatic fluids have caused prograde metamorphism during which anhydrous calc-silicate minerals including garnet and pyroxene have appeared. During the early retrograde stage, i.e. the mineralization sub-stage, lower temperature hydrothermal fluids have caused hydrolysis and carbonization because of which anhydrous calc-silicate minerals along with their fractures and microfractures are changed to hydrous calc-silicate (epidote and tremolite-actinolite), oxide (magnetite and hematite), sulfide (pyrite, chalcopyrite and bornite) and carbonate (calcite) minerals. During the late retrograde stage, relatively low temperature fluids have altered anhydrous and hydrous calc-silicate mineral assemblage formed during the previous stages into a very fine grained mineral assemblage including clay minerals, chlorite and iron hydroxides.
Presence of replacement textures in ore minerals and anhydrous calc-silicate minerals accompanied with open filling textures in the anhydrous calc-silicate minerals, for example oxide and sulphide veinlets within the garnet crystals, indicate that the mentioned ore minerals have been simultaneously generated with hydrous calc-silicate minerals (epidote and tremolite-actinolite) during the early prograde stage. The presence of minor amounts of wollastonite among the mineral assemblage of the Avan skarn, intergrowth of garnet and pyroxene, absence of reaction rim between garnet and clinopyroxene and absence of replacement textures indicate that these minerals have been simultaneously generated within the temperature ranges of 430–600 ºC and ƒO2 > 10-26, respectively.

Acknowledgements
The authors are grateful to the Journal of Economic Geology reviewers and editors for their constructive suggestions to the manuscript.

Reference
Baghban Asgharinezhad, S., 2012. Investigation of genesis, mineralogy and geochemistry of Fe-Cu skarn in Astamal area, NE Kharvana, Eastern Azarbaijan. MSc. Thesis, University of Tabriz, Tabriz, Iran, 185 pp. (in Persian with English abstract)
Calagari, A.A. and Hosseinzadeh, G., 2005. The mineralogy of copper-bearing skarn to the east of the Sungun-Chay River, East-Azarbaijan, Iran. Journal of Asian Earth Sciences, 28(4-6): 423-438.
Karimzadeh Somarin, A. and Moayed, M., 2002. Granite and gabbro-diorite associated skarn deposits of NW Iran. Ore geology reviews, 20(3-4): 127-138.
Mokhtari, M.A.A., 2008. Petrology, geochemistry and petrogenesis of Qaradagh batholith (east of Syahrood, Eastern Azarbaijan) and related skarn with considering mineralization. Ph.D. Thesis, Tarbiat Modares University, Tehran, Iran, 347 pp. (in Persian with English abstract)
Mokhtari, M.A.A., 2012. The mineralogy and petrology of the Pahnavar Fe skarn, in the Eastern Azarbaijan, NW Iran. Central European Journal of Geosciences, 4(4): 578-591.

Keywords


Aghanabati, S.A., 2004. Geology of Iran. Geological Survey of Iran, Tehran, 606 pp (in Persian).
Baghban Asgharinezhad, S., 2012. Investigation of genesis, mineralogy and geochemistry of Fe-Cu skarn in Astamal area, NE Kharvana, Eastern Azarbaijan. MSc. Thesis, University of Tabriz, Tabriz, Iran, 185 pp (in Persian with English abstract).
Berman, R.G., 1988. Internally- consistent thermodynamic data for minerals in the system Na2O–K2O–CaO–MgO–FeO–SiO2–Al2O3–Fe2O3–TiO2–H2O–CO2. Journal of Petrology, 29(2): 445-522.
Calagari, A.A. and Hosseinzadeh, G., 2005. The mineralogy of copper-bearing skarn to the east of the Sungun-Chay River, East-Azarbaijan, Iran. Journal of Asian Earth Sciences, 28(4-6): 423-438.
Deer, W.A., Howie, R.A. and Zussman, J., 1991. An Introduction to the rock forming minerals. 17th impression, Longman Scientific and Technical, London, 528 pp.
Einaudi, M.T., 1982a. Descriptions of skarns associated with porphyry copper plutons. In: S.R. Titley (Editor), Advances in geology of porphyry copper deposits, southwestern North America. University of Arizona Press, Tucson, pp. 1592-1606.
Einaudi, M.T., 1982b. General features and origin of skarns associated with porphyry copper plutons. In: S.R. Titley (Editor), Advances in geology of porphyry copper deposits, southwestern North America. University of Arizona Press, Tucson, pp. 185-210.
Einaudi, M.T. and Burt, D.M., 1982. Introduction, terminology, classification and composition of skarn deposits. Economic Geology and Bulletin of the Society of Economic Geologists, 7(4): 745-754.
Einaudi, M.T., Meinert, L.D. and Newberry, R.J., 1981. Skarn deposits. 75th Anniversary Volume, Society of Economic Geologists, USA.
Hosseinzadeh, G., 1999. Investigation on Anjerd Cu skarn deposit (N Ahar, Eastern Azarbaijan province). MSc. Thesis, Tabriz University, Tabriz, Iran, 118 pp (in Persian with English abstract).
Khain, V.E. and Koronousky, N.V., 1997. Caucasus. In: E.M. Moores and R.W. Fairbridge (Editors), Encyclopedia of European and Asian Regional Geology. Chapman and Hall, London, pp. 127-136.
Karimzadeh Somarin, A. and Moayed, M., 2002. Granite and gabbro-diorite associated skarn deposits of NW Iran. Ore geology reviews, 20(3-4): 127-138.
Khezri, M. and Moazen, M., 2001. Study of Andrian contact metamorphic, NW Iran. 5th Symposium of Iranian geological Society, Tehran University, Tehran, Iran (in Persian with English abstract).
Mehrpartou, M., Emami, M.H., Mirzaie, M. and Allaie Mahabadi, S., 1997. Geological map of Syahrood, scale 1:100000. Geological Survey of Iran.
Meinert, L.D., 1992. Skarns and skarn deposits. Geosciences Canada, 19(4): 145-162.
Meinert, L.D., 1993. Igneous petrogenesis and skarn deposits. In: R.V. Kirkham, W.D. Sinclair, R.I. Thorpe and J.M. Duke (Editors), Mineral deposit modeling. Geological Association of Canada, Ottawa, Canada: pp. 569-583.
Meinert, L.D., 1997. Application of skarn deposit zonation models to mineral exploration. Exploration and Mining Geology, 6(2): 185-208.
Mir Mohammadi, M.S., 1995. Geochemistry and petrology of Kamtal intrusion and its metamorphic haloe (east of Jolfa, NW Iran). MSc. Thesis, University of Tehran, Tehran, Iran, 194 pp (in Persian with English abstract).
Mojarad, M., 2003. Study of contact metamorphic occurrence around the Sheyvar intrusion. MSc. Thesis, Tabriz University, Tabriz, Iran, 118 pp (in Persian with English abstract).
Mokhtari, M.A.A., 2006. Controlling and introducing of promising areas in the Syahrood 1:100000 map. Geological Survey of Iran, 142 pp (in Persian).
Mokhtari, M.A.A., 2008. Petrology, geochemistry and petrogenesis of Qaradagh batholith (east of Syahrood, Eastern Azarbaijan) and related skarn with considering mineralization. Ph.D. Thesis, Tarbiat Modares University, Tehran, Iran, 347 pp (in Persian with English abstract).
Mokhtari, M.A.A., 2012. The mineralogy and petrology of the Pahnavar Fe skarn, in the Eastern Azarbaijan, NW Iran. Central European Journal of Geosciences, 4(4): 578-591.
Mokhtari, M.A.A. and Hosseinzadeh, R., 2012. Exploration of Astamal Fe mineralization (NE Kharvana, Eastern Azarbaijan). Geological Survey of Iran, Exploration report, Tehran, 85 pp (in Persian).
Mokhtari, M.A.A., Moinvaziri, H., Ghorbani, M.R., Mehrpartou, M. and Hosseinzadeh, G., 2012. Mineralogy and petrography of Kamtal skarn (north of Kharvana, Eastern Azarbaijan). Scientific Quarterly Journal, Geoscience, 22(86): 213-220 (in Persian with English abstract).
Mollaie, H., 1993. Petrochemistry and genesis of the granodiorite and associated Iron–copper skarn deposit of Mazraeh, Ahar, Eastern Azerbaijan, Iran. Ph.D. Thesis, University of Rookee, India 287 pp.
Mollaie, H., Yaghubpur, A.M. and Sharifiyan Attar, R., 2009. Geology and geochemistry of skarn deposits in the northern part of Ahar batholith, East Azarbaijan, NW Iran. Iranian Journal of Earth Sciences, 1(1): 15-34.
Moritz, R., Mederer, J., Ovtcharova, M., Selby, D., Chiaradia, M., Popkhadze, N., Gugushvili, V., Migineshvili, R., Melkonyan, R., Tayan, R., Vardanyan, A., Havokimyan, S., Ramazanov, V. and Mansurov, M., 2011. Major Cu, Au and Mo deposits of the Lesser Caucasus: Products of diverse geodynamic settings. 9th Swiss Geoscience Meeting, Zurich, Sweden.
Perkins, E.H., Brown, T.H. and Berman, R.G., 1986. PTX-SYSTEM: three programs for calculation of pressure–temperature–composition phase diagrams. Computers and Geoscience, 12(6): 749–755.
Ray, G.E., Webster, I.C.L. and Ettlinger, A.D., 1995. The distribution of skarns in British Columbia and the chemistry and ages of their related plutonic rocks. Economic geology, 90(4): 920-937.
Siahcheshm, K., 2002. Mineralogy, alteration and metasomatic changes in Pahnavar skarn deposit, east of Syahrood. MSc. Thesis, University of Tabriz, Tabriz, Iran, 139 pp (in Persian with English abstract).
Sosson, M., Rolland, Y., Müller, C., Danelian, T., Melkonyan, R., Kekelia, S., Adamia, S., Babazadeh, V., Kangarli, T., Avagyan, A., Galoyan, G. and Mosar, J., 2010. Subductions, obduction and collision in the Lesser Caucasus (Armenia, Azerbaijan, Georgia), new insights. Geological Society, London, Special Publications, 340: pp.329-352.
Vidal, C.C.E., Injoque-Espinoza, J., Sidder, G.B. and Mukasa, S.B., 1990. Amphibolitic Cu-Fe skarn deposits in the Central coast of Peru. Economic Geology, 85(7): 1447-1461.
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