The comparison of alteration zones in the Sungun porphyry copper deposit, Iran (based on fluid inclusion studies)

Czasopismo : Acta Geologica Polonica
Tytuł artykułu : The comparison of alteration zones in the Sungun porphyry copper deposit, Iran (based on fluid inclusion studies)

Autorzy :
Fedorowski, J.
Institute of Geology, Adam Mickiewicz University, Maków Polnych 16, PL-61-606 Poznań, Poland, jerzy@main.amu.edu.pl,
Dunlop, J.
Museum fur Naturkunde, Leibniz Institute for Research on Evolution and Biodiversity at the Humboldt University Berlin, Invalidenstrasse 43, D-10115 Berlin, Germany, jason.dunlop@mfn-berlin.de,
Wysocka, A.
Faculty of Geology, University of Warsaw, Al. Żwirki i Wigury 93, PL-02-089 Warszawa, Poland, anna.wysocka@uw.edu.pl,
Peskova, I.
Department of Geology and Paleontology, Faculty of Natural Sciences, Comenius University, Mlynska dolina, pav. G, 842 15 Bratislava, Slovakia, peskova@fns.uniba.sk,
Asghari, O.
Department of mining engineering, University of Kashan, Kashan, Iran, O.asghari@aut.ac.ir,
Abstrakty : The Sungun porphyry copper deposit (PCD) is located in East Azarbaijan, in northwestern Iran. The felsic rocks occur as stocks and dykes ranging in composition from quartz monzodiorite through quartz monzonite. The stocks are classified into porphyry stocks I and II. Porphyry stock II, hosting the copper ore, experienced an intense hydro-fracturing leading to the formation of stockwork-type veinlets and micro-veinlets of quartz, sulphides, carbonates and sulphates. Three distinct types of hydrothermal alteration and sulphide mineralization are recognized at Sungun (1) hypogene, (2) contact metasomatic (skarn), and (3) supergene. Hypogene alteration is developed in four kinds: potassic, phyllic, propylitic and argillic. Three types of fluid inclusions are typically observed at Sungun: (1) vapour-rich, two-phase, (2) liquid-rich two-phase and (3)multi-phase. Halite is the principal solid phase in multiphase inclusions. Primary multiphase inclusions (LVH type fluid inclusions) within the quartz crystals in quartz-sulphide and quartz-molybdenite veinlets (quartz associated with sulphide minerals) were selected for micro-thermometric analyses and considered to be suitable for pressure calculations and estimation of hydrothermal fluid density. Homogenization temperature, salinity, pressure and density were measured and calculated in forty-seven selected samples. None of the variables could distinguish the potassic from phyllic alteration zones clearly. In the potassic alteration zone, the average of homogenization temperature is about 413[degrees]C, while in the phyllic alteration zone its average is about 375[degrees]C. It was expected that the temperature in the potassic alteration zone would be higher than that in the phyllic zone, but the difference found was not very significant The fluid inclusion salinity within both alteration zones obviously relates to their homogenization temperature: the average salinity in the samples from the potassic zone is 46.3 (wt%NaCl equiv.), which is higher than that in the samples from the phyllic zone. Based on the estimated depth of the potassic alteration domain, it is expected that the lithostatic pressure was higher than in the phyllic alteration zone. According to the fluid inclusion studies and pressure calculation, it is estimated that the average pressure for the potassic alteration zone was about 512 (bars) while the average pressure for phyllic zone was about 310 (bars). The average density of fluids in the samples from the potassic alteration zone is 1.124 (g/cm[^3]), which is higher than that in the phyllic alteration zone (1.083 g/cm[^3]).

Słowa kluczowe : inkluzje fluidalne, przemiany potasowe, złoża miedzi porfirowej, Fluid inclusion, Phyllic alteration, Porphyry copper deposit, Potassic alteration,
Wydawnictwo : Faculty of Geology of the University of Warsaw
Rocznik : 2009
Numer : Vol. 59, no. 1
Strony : 93 – 109
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DOI :
Cytuj : Fedorowski, J. ,Dunlop, J. ,Wysocka, A. ,Peskova, I. ,Asghari, O. , The comparison of alteration zones in the Sungun porphyry copper deposit, Iran (based on fluid inclusion studies). Acta Geologica Polonica Vol. 59, no. 1/2009
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