Mineralogy and electron microprobe studies of magnetite in the Sarab-3 iron Ore deposit, southwest of the Shahrak mining region (east Takab)

Document Type : Research Article

Authors

Bu-Ali Sina University

Abstract

Introduction
There is an iron mining complex called Shahrak 60 km east of the Takab town, NW Iran. The exploration in the Shahrak deposit (general name for all iron deposits of the area) started in 1992 by the Foolad Saba Noor Co. and continued in several periods until 2008. The Shahrak deposit is comprised of 10 ore deposits including Sarab-1, Sarab-2, Sarab-3, Korkora-1, Korkora-2, Shahrak-1, Shahrak-2, Shahrak-3, Cheshmeh and Golezar deposits (Sheikhi, 1995) with a total 60 million tons of proven ore reserves. The Fe grade ranges from 45 to 65% (average 50%). The ore reserves of these deposits are different. Sarab-3 ore deposit with 9 million tons of 54% Fe and 8.95% S is located at the northeast of Kurdistan and in the Sanandaj-Sirjan structural zone at the latitude of 36°20´ and longitude of 47°32´.

Materials and methods
Sixty thin-polished, polished and thin sections are made for the study of mineralogy and petrology, and among them six thin-polished sections were selected for EPMA (Electron Probe Micro Analysis) on magnetite and hematite. EPMA was performed using the Cameca Sx100 electron microprobe at the Iran Mineral Processing Research Center (IMPRC) with wavelength-dispersive spectrometers.

Results and discussion
Based on field observations and petrographic studies, lithologic composition of intrusion (Miocene age) ranges within the diorite-leucodiorite, monzodiorite-quartz monzodiorite, granodiorite-granite. With the intrusion of those igneous bodies into carbonate rocks of the Qom Formation, contact metamorphism was formed. The formation of Sarab-3 iron deposit occurred at the three stages of metamorphism, skarnification and supergene. Based on field geology of the deposit, it is composed of endoskarn, exoskarn including Fe ore±sulfides. At the metamorphic stage, after intrusion of intrusive bodies in carbonate rocks, recrystallization took place and marble was formed. With more crystallization of magma, evolved hydrothermal fluids intruded into host rocks. Skarnification occurred at the two stages of progressive and regressive. At the progressive stage, the reaction of fluids and host rocks turned to the formation of anhydrous calc-silicate minerals such as garnet and clinopyroxene. At the regressive stage with the change of physicochemical conditions like decreasing temperature, these minerals converted to hydrous silicates (tremolite-actinolite, epidote) and phyllosilcates (chlorite, serpentine, talk, and phlogopite). Also, minerals such as oxides (magnetite and hematite), sulfides (pyrite and chalcopyrite) and calcite were formed. At a late stage, with activations of fluids, quartz-calcite mineralized veins formed. At the supergene stage, the oxidation process leads to the formation of alteration minerals from the main mineralization. Although there are magnesian minerals in the skarn, its main composition is calcic. The shape of the deposit is lentoid to horizontal and in some places bed formed along with some alteration halos. The ore minerals include low Ti-magnetite (with an average of 0.02 wt % Ti), hematite and sulfide minerals such as pyrite, pyrrhotite and chalcopyrite. Magnetite is the most important mineral with disseminated, vein, open-space filling, aggregate, accumulation, island and cataclastic textures. The magnetite at Sarab-3 is generated in 2 stages: At the first stage, magnetite has mass to mosaic textures that indicate the first phase of deposition in the area and at the second stage magnetite is gray magnetites that are placed as narrow bands around hematite or on the primary magnetite. Hematite in the area is formed either as hypogene hematite with plate or blade texture that is formed before the formation of early magnetite or supergene hematite that itself is formed due to alteration and weathering of magnetite in the superficial and shallow part of the deposit. In the surface area of the deposit, ore minerals are strongly altered to mixtures of oxide and hydroxide minerals like hematite, limonite and goethite which changed the color of the ore body to yellow, deep orange, red and brown. Pyrites are the most important sulfide minerals in the area that are formed in five stages respectively, mass texture (Py1), Melnikovity (py2), vein-veinlet (py3), inclusion (py4), and mineralized veins (py5). Sericitization, calcitization, serpentinization, chloritization, epidotization, uralitization, argilitization, propylitization and actinolitizion are the important alterations in the area from which chloritization-epidotization and calcitization in the ore and propylitic and argilitization alteration in the plutonic rocks are dominant. The EPMA analytical results on 23 points on magnetite and hematite mineral suggest that the amounts of TiO2 and V2O5 (0.03 wt % and 0.01 wt % in average, respectively) are low in contrast to MnO and Al2O3 (0.09 wt % and 1.59 wt % on the average, respectively). Therefore, it fits in the skarn ore deposit domain on Ni/(Cr+Mn) versus Ti+V and Ca+Al+Mn versus Ti+V discrimination diagrams of iron ore deposits (Dupuis and Beaudoin, 2011). High Mn in the rock samples of Sarab-3 may have resulted from the substitution of Fe by Mn in magnetite and hematite structure that can be a sign of hydrothermal skarn. Manganes, Al, Cu, Mg, and Ca show a negative correlation with Fe that may have resulted from the concentration and the substitution of these elements in tremolite-actinolite, epidote, chlorite, calcite, phlogopite and chalcopyrite. According to the chemistry of magnetite and plotting them on V2O5 versus TiO2 and V2O5 versus Cr2O3 diagrams, it can be recognized that the samples of the Sarab-3 deposit resemble to exoskarn magnetite of Goto and endoskarn Karakaen deposit of Senegal. Mineralographical and geochemical evidence from ore, the occurrence of iron in contact with the carbonates and calc silicates such as garnet, pyroxene, secondary calcite, epidote and chlorite suggest iron skarn genesis for the Sarab-3 deposit.

References
Dupuis, C. and Beaudoin, G., 2011. Discriminant diagrams for iron oxide trace element fingerprinting of mineral deposit types. Mineralium Deposita, 46(4): 319–335.
Sheikhi, R., 1995. Economic geology study of Shahrak Fe deposit, east of Takab. M.Sc.Thesis, Shahid Beheshti University, Tehran, Iran, 161 pp. (in Persian with English abstract)

Keywords

References

Aghanabati, A., 2004. Geology of Iran. Geological Survey of Iran, Tehran, 586 pp.
Azizi, H., 2003. Petrogenesis of contact metamorphic rocks and related Fe skarn in Shahrakarea, east of Takab. M.Sc. Thesis, University of Tehran, Tehran, Iran, 134 pp. (in Persian with English abstract)
Barker, D. S., 1995. Crystalization and alteration of quartz monzonite iron springs mining district, Uta: relation to association iron deposits. Economic Geology, 90(8): 2197–2217.
Barton, P.B.JR. and Skinner, B.J., 1979. Sulfide mineral stabilities. In: H.L. Barnes (Editor), Geochemistry of Hydrothermal Ore Deposit. John Wiley and Sons, New York, pp. 278–403.
Berman, R.G., Brown, T.H. and Greenwood, H.J., 1985. An internally consistent thermodynamic data base for minerals in the system Na2O–K2O–CaO– MgO–FeO–SiO2–Al2O3–Fe2O3–TiO2– H2O–CO2. Atomic Energy of Canada, Chalk River, Report 377, 62 pp.
Boomeri, M., Nakashima, K. and Lentz, D.R., 2009. The Miduk porphyry Cu deposit, Kerman, Iran: A geochemicalanalysis of the potassic zone including halogenelement systematics related to Cu mineralization processes. Journal of Geochemical Exploration, 103(1): 17–29.
Bucher, K. and Frey, M., 1994. Petrogenesis of metamorphic rocks, 6th edition complete revision of winkler's textbook. Springer Science, London, 428 pp.
Calagari, A.A. and Hosseinzadeh, G., 2006. The Mineralogy of copper-bearing skarn to the east of the Sungun-Chayriver, East-Azarbaidjan, Iran. Journal of Asian Earth Sciences, 28(4-6): 423–438.
Dare, S.A.S., Barnes, S.J. and Beaudoin, G., 2012. Variation in trace element content of magnetitecrystallized from a fractionating sulfide liquid, Sudbury, Canada: implications forprovenance discrimination. Geochemica et Cosmochimca Acta, 88(1): 27–50.
Dare, S.A., Barnes, S.J., Beaudoin, G., Meric, J., Boutroy, E. and Potvin- Doucet, C., 2014. Trace elements in magnetite as petrogenetic indicators. Mineralium Deposita, 49(7): 785–796.
Deer, W.A., Howie, R.A and Zussman, J., 1992. An introduction to the rock forming minerals. Longman, Harlow, Wiley, New York, 712 pp.
Dupuis, C. and Beaudoin, G., 2011. Discriminant diagrams for iron oxide trace element fingerprinting of mineral deposit types. Mineralium Deposita, 46(4): 319–335.
Einaudi, M.T., 1977. Petrogenesis of copper-bearingskarn at the Mason Valley mine, Yerington district, Nevada. Economic Geology, 72(5): 769–795.
Einaudi, M.T., Meinert, L.D. and Newberry, R.J., 1981. Skarn deposits. Economic Geology, 75th Anniversay, 24(3): 317–391.
Einaudi, M.T. and Burt, D.M., 1982. Introduction-terminology, classification and composition of skarn deposits. Economic Geology, 77(4): 745–754.
Fenodi, M. and Sayaerh, A.R., 2000. Geological map of HasanabadYasoukand, scale 1:100,000. Geological Survey of Iran.
Ferdowsi, R., 2011. The Study of metasomatic alteration in the around granitoids intrusion KamtelKharvana- Eastern Azarbaijan. M.Sc. Thesis, Tabriz University, Tabriz, Iran, 123 pp. (in Persian with English abstract).
Franchini, M.B., Meinert, L.D. and Valles, J.M., 2002. First occurrence of ilvaite in a Au skarn deposit. Economic Geology, 97(5): 1119–1126.
Frietsch, R., 1973. The Origin of the Kiruna iron ores. Geologiska Föreningen i Stockholm Förhandlingar, 95(4): 375−380.
Frost, B.R., 1991. Stability of oxide minerals in metamorphic rocks. In: D.H. Lindsley (Editor), Reviews in Mineralogy. Oxide Minerals: Petrologic and magnetic significance. Mineralogical Society of America, Washington, PP. 469–487.
Ghiorso, M.S. and Sack, O., 1991. Thermochemistry of the oxide minerals. In: D.H. Lindsley (Editor), Oxide Minerals: Petrologic and Magnetic Significance. Mineralogical Society, America, pp. 221–264.
Grant, F.S., 1985. Aeromagnetics, geology and ore environments, I. magnetite in igneous, sedimentary and metamorphic rocks: An overview. Geoexploration, 23(3): 303–333.
Guilbert, J.M. and Park, C.F., 1997. The Geology of ore deposits. W.H. Freeman and Company, Oxford and New York, 985 pp.
Hammarstrom, J.M., Orris, G.J., Bliss, J.D. and Theodore, T.G., 1989. A Deposit Model for Gold-Bearing Skarns; Fifth Annual V.E. McKelvey Forum on Mineral and Energy Resources. United States Geological Survey Circular, 1035(1): 27–28.
Harriss, N.B. and Einaudi, M.T., 1982. Skarn deposits in the Yeringtin, Nevada: Metasomatic skarn evolution near Ludwig. Economic Geology, 77(4): 877–898.
Hosseinzadeh, Gh., 1999. Investigation ofcopperskarn-type deposit, Anjerd, northeastern of Ahar. M.Sc. Thesis, Tabriz University, Tabriz, Iran, 118 pp. (in Persian with English abstract)
Hu, H., Lentz, D., Li, J., McCabral, T., Zhao, X. and Hall, D., 2015. REE quilibration processes in magnetite from iron skarn deposits. Economic Geology, 110(1): 1–8.
Huberty, J.M., Konishi, H., Heck, P.R., Fournelle, J.H., Valley, J.W. and Xu, H., 2012. Silician magnetite from the Dales Gorge Member of the Brockman Iron Formation, Hamersley Group, Western Australia. American Mineralogist, 97(1): 26–37.
Karimzadeh Somarin, A. and Moayyed, M., 2002. Granite and gabbrodiorite-associated skarn deposits of NW Iran. Ore Geology Reviews, 20(3): 127–138.
Kimia Maaden Sepahan Company., 2011. Simiplified geological map of Sarab-3 deposit, scale 1:1000. Geological Survey of Iran.
Khodaei, L., 2015. Mineralogy and geochemistry of Sarab-3 Fe deposit (Shahrak, East ofTakab). M.Sc. Thesis, Bu-Ali Sina University, Hamedan, Iran, 164 pp. (in Persian with English abstract)
Lentz, D.R., 2005. Mass-balance analysis of mineralized skarn systems: Implications for eplacement processes, carbonate mobility, and permeability evolution. In: J. Mao and F.P. Bierlein (Editors), Mineral Deposit Research: Meeting the Global Challenge. Proceedings of the Biennial SGA Meeting, Beijing, China, pp. 421–424.
Lindsley, D.H., 1976. The Crystal chemistry and structure of oxide minerals as exemplified by the Fe–Ti oxides. In: D. Rumble III (Editor), Oxide Minerals. Review Mineral, Mineral Society, America, pp. L1–L60.
Maanijou, M., Rasa, E. and Lentz, D., 2012. Petrology, geochemistry, and stable isotope studies of the Chehelkureh Cu-Zn-Pb deposit, Zahedan, Iran. Economic Geology, 107(4): 683–712.
Maanijou, M. and Salemi, R., 2015. Mineralogy, chemistry of magnetite and genesis of Korkora-1 iron deposit (East of Takab). Journal of Economic Geology, 6(2): 355-376. (in Persian with English abstract)
Marschik, R., Spikings, R. and Kuscu, I., 2008. Geochronology and stable isotope signature ofalteration related to hydrothermal magnetite ores in Central Anatolia, Turkey. Mineralium Deposita, 43(1): 111–124.
McClenaghan, M.B., 2005. Indicator mineral methods in mineral exploration: geochemistry, exploration environment analysis. Geological Society of London, 5(3): 233–245.
Meinert, L.D., 1992. Skarn and skarn deposits. Geosciences Canada, 19(4): 145–162.
Meinert, L.D., Dipple, G.M. and Nicolescu, S., 2005. World skarn deposits. In: J.W. Hedenquist, J.F.H. Thompson, R.J. Goldfarb and J.P. Richards (Editors), Economic geology 100th anniversary volume. Society of Economic Geologists, Colorado, pp. 299–336.
Mollai, H., Sharma, R. and Pe-PiPer, G., 2009. Coppermineralization around the Ahar (NW Iran): evidence for evolution and the origin of the skarnore deposit. Ore Geology Reviews, 35(3–4):401–414.
Monteiro, L.V.S., Xavier, R.P., Hitzman, M.W., Juliani, C., Filho, C.R.S. and Carvalho, E.R., 2008. Mineral chemistry of ore and hydrothermal alteration at the Sossego iron oxide–copper –gold deposit, Carajas Mineral Province, Brazil. Ore Geology Reviews, 34(3): 317–336.
Mucke, A. and Cabral, A.R., 2005. Redox and nonredox reactions of magnetite and hematite in rocks.Chemie der Erde, 65(3): 271–278.
Nadoll, N., Angerer, Th., Mauk, J., French., D. and Walshe, J. 2014. The Chemistry of hydrothermal magnetite: A Review. Ore Geology Reviews, 61(1): 1–32.
Nadoll, P., Mauk, J.L., Hayes, T.S., Koenig, A.E. and Box, S.E., 2012. Geochemistry of magnetite from hydrothermal ore deposits and host rocks of the Mesoproterozoic Belt Supergroup, United States. Economic Geology, 107(6):1275–1292.
Niiranen, T., Manttari, I., Poutiainen, M., Nicholas, H.S. and Jodie, A., 2005. Genesis of Palaeoproterozoic iron skarns in the Misi region, northern Finland. Mineralium Deposita, 40(2): 192–217.
Nystrom, J.O. and Henriquez, F., 1994. Magmatic features of iron ore of the Kiruna type in Chile and Sweden: ore textures and magnetite geochemistry. Economic Geology, 89(4): 820–839.
Oyman, T., 2010. Geochemistry, mineralogy and genesis of the Ayazmant Fe-Cu skarn deposition in Ayvalik, (Balikesir), Turkey. Ore Geology Reviews, 37(3): 175–201.
Park, Jr. C.F. and Mac Diarmid, R.A., 1975. Ore deposits. W.H. Freeman and Company, SanFrancisco, 529 pp.
Pournik, P., 2007. Evaluation of ore reserve of Shahrak Fe deposit report. Sabanour Steel Providing Material Company, Tehran, Internal Report 1, 350 pp. (in Persian)
Ramdohr, P., 1980. The Ore minerals and their inter growths. Pergamon Press, Oxford, 1205 pp.
Razjigaeva, N.G. and Naumova, V.V., 1992. Trace element composition of detrital magnetite from coastal sediments of Northwestern Japan Sea for provenance study. Journal of Sedimentary and Petrology, 62(5): 802−809.
Reed, M.H., 1997. Hidrotermal alteration and its relationships to ore fluid composition. In: H.L. Barnes (Editor), Geochemistry of Hidrotermal Ore Deposits. John Wiley, London, pp. 303–358.
Salemi, R., 2013. The study of fluid inclusion and geochemistry of Korkora-1 iron deposit (Shahrak, east Takab). M.Sc. Thesis, Bu-Ali Sina University, Hamedan, Iran, 186 pp. (in Persian with English abstract)
Schwartz, M.O. and Melcher, F., 2004. The Faleme iron district, Senegal. Economic Geology, 99(5): 917–939.
Scott, S.D., 1974. Experimental methods in sulfide synthesis. In: P.H. Ribbe (Editor), Sulfide Mineralogy. Mineralogical Society, American, pp. S1–S38.
Sheikhi, R., 1995. Economic geology study of Shahrak Fe deposit, east of Takab. M.Sc.Thesis, Shahid Beheshti University, Tehran, Iran, 161 pp. (in Persian with English abstract)
Shelly, D., 1993. Microscopic study of igneous and metamorphic rock.Champan and Hall, London, 630 pp.
Shimazaki, H., 1980. Characteristics of skarn deposits and related magmatism in Japan. Economic Geology, 75(2): 173–183.
Siahcheshm, K., 2002. Mineralogy, alteration and metasomaticevolutionofPahnavarskarn deposit (east of SiahRoud). M.Sc. Thesis, Tabriz University, Tabriz, Iran, 139 pp. (in Persian with English abstract)
Singoyi, B. and Zaw, K., 2001. A petrological and fluid inclusion study of magnetite–scheeliteskarn mineralization at Kara, northwestern Tasmania: implications for ore genesis. Chemistry Geology, 173:(1–3): 239–253.
Tallarico, F.H.B., Figueiredo, B.R., Groves, D.I., Kositcin, N., McNaughton, N.J., Fletcher, I.R. and Rego, J.L., 2005. Geology and shrimp U–Pb geochronology of the Igarape Bahia deposit, Carajas copper–gold belt, Brazil: An Archean (2.57 Ga) example of iron–oxide Cu–Au–(U– REE) mineralization. Economic Geology, 100(1):7–28.
Vallance, J., Fontbote, L., Chiaradia, M., Markowski, A., Schmidt, S. and Vennemann, T., 2009. Magmatic-dominated fluid evolution in the Jurassic Nambija gold skarn deposits (southeastern Ecuador). Mineralium Deposita, 44(4): 389–413.
Whitney, D.L. and Evans, B.V., 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1): 185–187.
Xu, G. and Lin, X., 2010. Geology and geochemistry of the Changlongshanskarn iron deposit, Anhui province, China. Ore Geology Reviews, 16(1): 91–106.
Send comment about this article
CAPTCHA Image

Files

Cited by

History

  • Receive Date: 05 June 2016
  • Accept Date: 13 December 2016

Share

How to cite

Statistics