Study of Petrogenesis, Modeling And Involved Fluids in Igneous Rocks in The area of Tanurjeh Deposit

Autores

Palavras-chave:

Petrogenesis, Involved fluids, Igneous rocks, Tanurjeh deposit

Resumo

Tanurjeh porphyry copper-gold deposit is located in Khorasan Razavi province, south of Neishabour and 5 km south of Tanurjeh village. The types of rocks in the study area include andesite, porphyry diorite, quartz porphyry diorite, porphyry granodiorite, rhyolite, rhyodacite and tuff, and metal minerals include magnetite, chalcopyrite, pyrite, iron oxides and hydroxides, covellite, malachite, galena, sphalerite, malachite, rutile and gold particles. To accurately detect copper and gold anomalies from the field, the fractal geometry-number method was used. A combination of exploratory layers was performed to identify suitable areas for exploratory drilling. To determine the temperature of the deposit formation and its chemical properties, salinity of the trapped fluids was taken. Evaluation of the involved fluids indicates that the primary fluids have high salinity and the secondary fluids have medium salinity and primary fluids homogenize at 319 to 514 ° C and secondary fluids at 138 to 345 ° C. These results show the mineralization of copper and gold in terms of porphyry system type and mineralization can continue to depths of more than 350 meters. However, the absence of stock quartz veins, the presence of a large siliceous zone and the lack of mineralization of copper are some of the things that make a difference compared to porphyry copper systems. As a result, this area can be considered as a porphyry copper-gold mineralization area in which mineralization has been done in depth and in the vicinity of the intrusion mass and in some places points are seen as streaks on the surface.

Referências

Adabi, M.H.; Sedimentary Geochemistry. Arian Zamin Research Center, 475, 2004. p. 374-411.

Aghanbati, A.; the Geology of Iran, Geological Survey of Iran, 2004. p 606.

Bazoobandi, M.H.; Arian, M.A.; Emami, M.H.; Tajbakhsh, G.; Yazdi, A.; Petrology and Geochemistry of Dikes in the North of Saveh in Iran, Open journal of marine science. 6(02), 2016. p. 210.

Behroozi, A., Geological map and report of Faizabad 1.100000, Geological Survey of Iran, 1987.

Behroozi, A.; Vaezipour M.J.; Alawi Tehrani, N.; Kholghi, M.; Geological map of Torbat-e Heydarieh 1/250,000, Geological Survey and Mineral Exploration Organization, 1991.

Bernhardet.;, Middle Tertiary volcanic rocks from the southern Sabzevar zone Khorasan (NE Iran), Geotravers, 1983. p.277-284.

Borinseko A. S.; Study of the salt composition of solution in gas-liquid inclusions in mineral by the cryometric method, Soviet Geol. & Geographys, 18, 1977. p.11-19.

Breshenkov B. K.; on the problem of the genesis of jarosites, Compl. Rend (doklady) de l’ Acad. des Sciences de l’ URSS, 52(4), 1946. p. 239-332.

Butter B. S.; Loughlin G. F.; Heikes V C.; The ore deposits of Utah, USGS., Prof. 111. 1920.

Defant M. J., et al, Dacite genesis via both slab melting and differentiation, petrogenesis of La Yeguada volcanic complex, Panama. Jour. Petrol. 32, 1991. p. 1101-1142.

Earth Science Database, www.ngdir.com

Ermakov N.P. 1965, Research on the nature of mineral –forming solutions with special reference to data from fluid inclusions. Int. Ser. Mongor. Earth Sci. 22, Pergamon Press Oxford.

Geological Survey of Iran.; Initial introduction to antimony and arsenic mineralization in Kashmar region. 1988.

Ghorbani, M.; Economic Geology of Mineral and Natural Resources of Iran (Volume I), Arian Zamin Research Center. 2007. p.515.

Harris N.B.W., Pearce J. A., and Tindle A.G., 1986, Geochemical characteristics of collision zone magmatism. In Coward M.P., and Reis, A.C., (eds), collision tectonicts Spec. publ. Geol. Soc. 19, 67-81.

Hassani Pak, A.A.; (Third Edition), Principles of Geochemical Exploration (Minerals), University of Tehran, 1998. p. 600.

Hassani Pak, A.A.; Exploratory geochemistry (rock environment), Hormozgan University, 1997. p. 274.

Hedenquist J. W., Lowenstern J. B., 1994, The role of magmas in the formation of hydrothermal ore deposits, Nature 370, 519-527.

Hutton C. O., Bowen O. E., , An occurrence of jarosite in altered volcanic rocks of Stoddard Mountain, San Bernardino county, California , American mineralogist, 5, 556-561.

Irvine T.N., and Baragar W.R.A., 1971, A guide to chemical classification of the common volcanic rocks: Can. J. Sci. 8, 523-548.

Ishihara S., 1981, The granitoide series and mineralization, Econ. Geol., 75, 458-484.

Jafari, H.R.; Yazdi, A.; Radioactive Anomalies in 1: 50000 Dehbakri Sheet, South of Kerman Province, Iran, Open Journal of Geology. 4, 2014. p. 399-405. doi: 10.4236/ojg.2014.48031.

Karimpour, M.H.; How to form and select suitable environments for exploration of epithermal gold reserves in Iran, Second Mining Symposium, Kerman. 1988.

Karimpour, M.H.; Saadat, S.; Applied Economic Geology (new edition), Mashhad Publishing, 2002. p.535.

Karimpour, M.H.; Saadat, S.; Malekzadeh Shafaroodi, A.; Identification and Introduction of Fe-Oxides Cu-Au Mineralization and Magnetite Related to Khaf-Kashmar-Kashmar-Skand Range Volcanic-Plutonic Belt, 21st Earth Sciences Conference. 2002.

Karimpour, M.H.; Saadat, S.; Satellite Information Processing, Study of Alteration, Geochemistry and Mineralization of Copper-Porphyry Gold in the North and Northeast of Kashmar, Mineral Resources Research Center of Eastern Iran, Faculty of Science, Ferdowsi University of Mashhad. 2004.

Macpherson C. G., Dreher S. T., Thirwall M. F., 2006, Adakites without slab melting high pressure differentiation of island arc magma, Mindanaho, the Philippines, Elsevier, EPSL, 243, 581-593.

Mc Kenzi D., 1972, Active tectonics of the Mediterranean region., Geophys. J.R. Astr. Soc., 30, 109-165.

McDonough W.F., Sun S., Ringwood A. E., Jagoutz E., and Hofmann A. W., 1991, K, Rb and Cs in the earth and moon and evolution of the earth's mantle. Geochim. Cosmochim. Acta, Ross Taylor Symposium volume.

Middlemost E.A.K., 1985, Magmas and magmatic rocks. Longman, London.

Muller R., Walter R., 1983, Geology of the Precambrian-Paleozoic Taknar inlier northwest of Kashmar, Khorasan Province Northeast Iran. Geol. Surv. Iran, ISSN 0075-0448, Rep. No. 51. 165-183.

Palacios C., Herial G., Townley B., Maksaer V., Sepulveda F., Plearseval Ph., Rivas P., Lahsen A., Parada M., 2001, The Composition of gold in the Cerro Casale gold-Rich porphyry deposit, Maricunga Belt, Northern Chile, The Canadian Mineralogist, 39, 907-915.

Peccerillo R., and Taylor S.R., 1976, Geochemistry of Eocene calc-alkaline volcanic rocks from the Kastamonu area, northern Turkey. Contrib. Mineral. Petrol., 58, 63-81.

Porter R. W. II, 1977, Pressure correction for fluid-inclusion homogenization temperatures based on the volumetric properties of the system NaCl-H2O. J. Res. U.S.Geol. Surv. 5, 603-607.

Roedder E., 1984, the fluids in salt. Am. Mineral. 69, 413-439.

Rollinson H., Tarney J., 2005, Adakites- the key to understanding LILE depletion in granulites, Elsevier, Lithos 79, 61-81.

Sanders A. D. and Tarney J., 1984, Geochemical characteristics of basaltic volcanics within back-arc basin. In: Kokelaar B.P and Howells H. F., Marginal basin geology, Spec. Publ. Geol. Soc. London 16, 59-76.

Sasaki A., Ishihara S., 1979, Sulfur isotopic composition of the magnetite – series and ilmenite – series granitoids in Japan, Contr. Mineralogy Petrology, 68, 107-115.

Sillitie R. H., 1996, Granite and metal deposits : Episode 19,4, 126-133.

Sillitoe R.H., 1993, Gold-rich porphyry copper deposits, geological model and exploration implications. Geological Association of Canada Special Paper 40, 465-478.

Vila T., Sillitoe R.H., 1991, Gold-Rich porphyry systems in the Maricunga Belt, northern Chile, Econ. Geol., 86, 1238-1260.

Weaver B. and Tarney J., 1984, Empirical approach to estimating the composition of the continental crust. Nature, 310, 575-57.

Wellman H.W., 1966, Active wrench faults of Iran, Afghanistan and Pakistan. Geol. Rundsch., 55(3), 716-735.

Westra G., Keith S. B., 1981, Classification and genesis of stockwork molybdenum deposits, Econ. Geol. 76, 844-873.

Wilkinson J. J., 2001, Fluid inclusions in hydrothermal ore deposits, Elsevier, Lithos 55, 229-272.

Winchester J.A., and Floyd P.A. 1977. A re-appraisal of the use of trace elements to classify and discriminate between magma series and their differentiation products using immobile elements: Chem. Geol. 20, 325-343.

Yazdi, A.; ShahHoseini, E.; Razavi, R.; AMS, A method for determining magma flow in Dykes (Case study: Andesite Dyke). Research Journal of Applied Sciences, 11(3), 2016. p. 62-67.

Yazdi, A.; Sharifi Teshnizi, E.; Effects of contamination with gasoline on engineering properties of fine-grained silty soils with an emphasis on the duration of exposure, SN Applied Sciences 3(7), 2021. p.1-24.

Yazdi, A.; Ziaaldini, S.; Dabiri, R.; Investigation on the Geochemical Distribution of REE and Heavy Metals in Western Part of Jalal-Abad Iron Ore Deposit, Zarand, SE of Iran, Open journal of ecology. 5(09), 2015. p. 460.

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2021-12-31

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Bagherzadeh, N. A., Alirezaei, S., Jafarirad, A., & Afzal, P. (2021). Study of Petrogenesis, Modeling And Involved Fluids in Igneous Rocks in The area of Tanurjeh Deposit. Revista Geoaraguaia, 11(02), 49–74. Recuperado de https://periodicoscientificos.ufmt.br/ojs/index.php/geo/article/view/13015

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