Geochemistry and the origin of the Mamouniyeh iron ore-terra rossa deposit, Markazi Province - Iran

Document Type : Research Article

Authors

Behbahan Branch, Islamic Azad University

Abstract

Introduction
Iron is among the metals whose ore deposits are not confined to a specific geologic period of crustal formation and they have formed in various geologic environments during previous periods (Ghorbani, 2007). About 95% of iron ore deposits have sedimentary origin and have formed due to chemical deposition from ancient sea water. The remaining percent is the result of alteration and magmatic activities (Gutzmer and Beukes, 2009). In sedimentary environments, a large amount of sedimentary iron minerals have formed resulting in different iron facies. Iron oxide facies are of the most important facies (James, 1954). The most important Iranian iron deposits are located in Central Iran, Sanandaj- Sirjan and East Iran zones, and the Kordestan area (Ghorbani, 2007). In the Orumiyeh-Dokhtar Zone, many iron ore deposits have been formed in conjunction with granitic and granodioritic plutons related to Oligocene-Miocene plutonic and volcanic activities (Hoshmandzadeh, 1995). The Mamouniyeh iron ore-terra rossa deposit is located in the Orumiyeh-Dokhtar volcanic zone. Iron mineralization have occurred in trachytic-trachyandesitic lavas and pyroclastic rocks of Pliocene age.

Materials and methods
A total of 28 rock samples were picked up from ore and host rocks during field observations. Petrographical and mineralogical studies were performed on 15 thin sections of ore and host rocks. XRD studies were performed on 3 ore samples. In order to investigate the geochemistry of the ore, 10 samples were analyzed for major, trace and rare earth elements (REEs) using the ICP-MS method.

Result
Field and mineralogical studies reveal that the ore is composed of hematite along with crypto-crystalline silica as alternating layers of various thickness and color. The existence of alternating layers of hematite and quartz implies that the ore is similar to banded iron formations, but on a smaller scale, related to submarine hydrothermal activities. Silica is found as chert and minor jasper. Some secondary dolomite and calcite, filling the fractures and open spaces are found. Clay minerals are also minor constituents of the ore. The remaining fossils of green-blue algae indicate the conditions of iron deposition and effective biological processes in oxidizing Fe+2 and creation of new oxide minerals in a sedimentary basin. XRD studies show that tetraferriannite, hisingerite, barite, dolomite and calcite are present in addition to dominant hematite and quartz minerals. Hisingerite is formed in sedimentary iron deposits during hydrothermal alteration (Whelan and Goldich., 1961). Tetraferriannite occurs in low grade iron formations (Miyano, 1982). Structurally, the mineralization is controlled by a tectonic zone in which abundant breccias and faults are well found.
The amount of Fe2O3 ranges between 11.62% and 65.73%, with an average value of 31% Fe2O3. The amounts of Cr (3-95 ppm) and Zr (

Keywords

References

Ahmad, T. and Posht-Kuhi, M., 1993. Geochemistry and Petrogenesis of Urumiah–Dokhtar volcanics around Naien and Rafsanjan Areas: A Preliminary Study, Treatise on the Geology of Iran. Iranian Ministry of Mines and Metals, Tehran, 90 PP.
Alavi, M., 2004. Regional Stratigraphy of the Zagros Fold-Thrust belt of Iran and its Proforeland Evolution. American Journal of Science, 304(1): 1-20.
Basta, F.F., Maurice, A.E., Fontbote, L. and Favarger, P.Y., 2011. Petrology and geochemistry of the banded iron formation (BIF) of Wadi Karim and Um Anab. Eastern Desert, Egypt: implications for the origin of Neoproterozoic BIF. Precambrian Research, 187(3–4): 277–292.
Bau, M., 1999. Scavenging of dissolved yttrium and rare earths by precipitating iron oxyhydroxide: experimental evidence for Ce oxidation, Y-Ho fractionation, and lanthanide tetrad effect. Geochimica et Cosmochimica Acta, 63(1): 67–77.
Bau, M. and Dulski, P., 1996. Distribution of yttrium and rare-earth elements in the Penge and Kurumaniron- formations, Transvaal Supergroup, South Africa. Precambrian Research, 79(1-2): 37–55.
Cornell, R.M. and Schwertmann, U., 2003. The iron oxides. Structure, properties, reactions, occurrences and uses. Wiley and Sons, Weinheim, 659 pp.
Cox, G.M., Halverson, G.P., Minarik, W.G., Heron, D.P., Macdonald, F.A., Bellefroid, E.J. and Strauss, J.V., 2013. Neoproterozoic iron formation: An evaluation of its temporal, environmental and tectonic significance. Chemical Geology, 362(Special issue): 232–249.
Dimitrijevic, M.D., 1973. Geology of Kerman Region. Institute for geological and mining exploration and investigation of nuclear and other mineral raw materials. Iran Geological Survey, Tehran, Report 52, 334 pp.
Douville, E., Bienvenu, P., Charlou, J.L., Donval, J.P., Fouquet, Y., Appriou, P. and Gamo, T., 1999. Yttrium and rare earth elements in fluids from various deep-sea hydrothermal systems. Geochimica et Cosmochimica Acta, 63(5): 627–643.
Dymek, R.F. and Klein, C., 1988. Chemistry, petrology and origin of banded iron formation lithologies from 3800 Ma Isua supracrustal belt, West Greenland. Precambrian Research, 39(4): 247–302.
Ehya, F., 2012. Rare earth element and stable isotope (O, S) geochemistry of barite from the Bijgan deposit, Markazi Province, Iran. Mineralogy and Petrology, 104(1-2):81–93.
Ghasemi, A. and Talbot, C.J., 2006. A new tectonic scenario for the Sanandaj-Sirjan Zone, Iran. Journal of Asian Earth Sciences, 26(6): 683–693.
Ghorbani, M., 2007. Economic geology of mineral and natural resources of Iran. Arian zamin, Tehran, 492 pp.
Glasby, G.P. and Schulz, H.D., 1999. Eh Ph diagrams for Mn, Fe, Co, Ni, Cu and as under seawater conditions: application of two new types of eh ph diagrams to the study of specific problems in marine geochemistry. Aquat. Marine Geochemistery, 5(3): 227–248.
Gross, G.A., 1980. A classification of iron formations based on depositional environments. The Canadian Mineralogist, 18(2): 215-222.
Gutzmer, J. and Beukes, N.J., 2009. Iron and Manganese Ore Deposits: Mineralogy, Geochemistry and Economic Geology. In: B. De Vivo, B. Grasemann and K. Stüwe (Editors), Encyclopaedia of Life Support Systems. UNESCO, Paris, pp. 43-69.
Hoshmandzadeh, A.R., 1995. Iran geology, Iron deposit of Iran. Geological Survey of Iran, Tehran, 145 pp.
James, H.L., 1954. Sedimentary facies of iron formation. Economic Geology, 49(1-3): 235-293.
Karimpour, M.H. and Saadat, S., 2010. Applied economic geology. Mashhad University Press, Mashhad, 535 pp.
Laznicka, P., 2006. Giant Metallic Deposits Future Sources of Industrial Metals. Springer Berlin Heidelberg, New York, 732 pp.
McDonough, W.F. and Sun, S.S., 1995. The composition of the earth. Chemical Geology, 120(3-4):223–253.
Michard, A., Albarede, F., Michard, G., Minster, J.F. and Charlou, J.L., 1983. Rare-earth elements and uranium in high temperature solutions from East Pacific Rise hydrothermal vent field (13◦N). Nature, 303(5920): 795–797.
Mitra, A., Elderfield, H. and Greaves, M.J., 1994. Rare earth elements in submarine hydrothermal fluids and plumes from the Mid-Atlantic Ridge. Marine Chemistry, 46(3): 217–235.
Miyano, T., 1982. Ferri-annite from the Dales Gorge Member iron-formations, Wittenoom area, Western Australia. American Mineralogist, 67(1-2): 1179-1194.
Moradian, A., 1997. Geochemistry, geochronology and petrography of feldspathoid bearing rocks in Urumieh–Dokhtar volcanic belt. Unpublished PhD thesis, University of Wollongong, Wollongong, Australia, 165 pp.
Mucke, A., Annor, A. and Neumann, U., 1996. The Algoma-type iron-formations of the Nigerian meta volcano-sedimentary schist belts. Mineralium Deposita, 31(1-2): 113-122.
Murray, R.W., Buchholtz ten Brink, M.R., Jones D.L, Gerlach, D.C. and Russ, G.P., 1990. Rare earth elements as indicators of different marine depositional environments in chert and shale. Geology, 18(3): 268–271.
Namaki, L., 2013. Geophysics proposal for considering Mamouneyeh deposit. Kian kavan zamin company, Tehran, Report 1, 9 pp.)
Planavsky, N., Bekker, A., Rouxel, O.J., Kamber, B., Hofmann, A., Knudsen, A. and Lyons, T.M., 2010. Rare Earth Element and yttrium compositions of Archean and Paleoproterozoic Fe formations revisited: new perspectives on the significance and mechanisms of deposition. Geochimica et Cosmochimica Acta, 74(22): 6387–6405.
Prasad, K.S.S., Sankar, D.B. and Reddy, Y.V. 2012. Geochemistry and Origin of Banded Iron-Formation from the Granulitic Terrain of North Arcot District. Chemical Science Transactions, 1(3): 482-493.
Shahabpour, J., 2007. Island-arc affinity of the Central Iranian Volcanic Belt. Journal of Asian Earth Sciences, 30(3-4): 652–665.
Sun, H., Wu, J., Yu, P. and Li, J., 1998. Geology, geochemistry and sulfur isotope composition of the Late Proterozoic Jingtieshan (Superior-type) hematite-jasper-barite iron ore deposits associated with stratabound Cu mineralization in the Gansu Province. Mineralium Deposita, 34(1): 102-112.
U.S. Geological Survey., 2013. Iron ore. Mineral Commodity Summaries, Virjinia, 85 pp.
Whelan, J.A. and Goldich, S.S., 1961. New data for Hisingerite and neotocite. American Mineralogist, 46: 1412-1423.
Whitney, D. and Evans, B., 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1): 185-187.
Wilshire, H.G., 1958. Alteration of olivine and orthopvroxene in basic lavas and shallow intrusive. American Mineralogist, 43: 12-146.
Zohrab, E. and Haddadan, M., 2009. Geological map of Zaveyeh, scale 1:100,000. Geological Survey of Iran.
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  • Receive Date: 16 January 2015
  • Accept Date: 06 February 2016

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