Abstract
Situated about 130 km northeast of Tabriz (northwest Iran), the Mazra’eh Shadi deposit is in the Arasbaran metallogenic belt (AAB). Intrusion of subvolcanic rocks, such as quartz monzodiorite-diorite porphyry, into Eocene volcanic and volcano-sedimentary units led to mineralisation and alteration. Mineralisation can be subdivided into a porphyry system and Au-bearing quartz veins within andesite and trachyandesite which is controlled by fault distribution. Rock samples from quartz veins show maximum values of Au (17100 ppb), Pb (21100 ppm), Ag (9.43ppm), Cu (611ppm) and Zn (333 ppm). Au is strongly correlated with Ag, Zn and Pb. In the Au-bearing quartz veins, factor group 1 indicates a strong correlation between Au, Pb, Ag, Zn and W. Factor group 2 indicates a correlation between Cu, Te, Sb and Zn, while factor group 3 comprises Mo and As. Based on Spearman correlation coefficients, Sb and Te can be very good indicator minerals for Au, Ag and Pb epithermal mineralisation in the study area. The zoning pattern shows clearly that base metals, such as Cu, Pb, Zn and Mo, occur at the deepest levels, whereas Au and Ag are found at higher elevations than base metals in boreholes in northern Mazra’eh Shadi. This observation contrasts with the typical zoning pattern caused by boiling in epithermal veins. At Mazra’eh Shadi, quartz veins containing co-existing liquid-rich and vapour-rich inclusions, as strong evidence of boiling during hydrothermal evolution, have relatively high Au grades (up to 813 ppb). In the quartz veins, Au is strongly correlated with Ag, and these elements are in the same group with Fe and S. Mineralisation of Au and Ag is a result of pyrite precipitation, boiling of hydrothermal fluids and a pH decrease.
References
Barnes, H.L., 1979. Solubilities of ore minerals. [In:] H.L, Barnes (Ed). Geochemistry of hydrothermal ore deposits, 2nd ed. John Wiley & Sons, New York. pp 404-410.
Bodnar, R.J., 1993. Revised equation and table for determining the freezing point depression of H2O-NaCl solutions. Geochimca et Cosmochimica Acta 57, 683-684.
Browne, P.R.L., 1978. Hydrothermal alteration in active geothermal fields. Annual Reviews of Earth and Planetary Science 6, 229-250.
Browne, P.R.L. & Ellis., A.J., 1970. The Ohaki-Broadlands hydrothermal area, New Zealand: Mineralogy and related geochemistry. American Journal of Science 269, 97-131.
Buchanan, L.J., 1981. Precious Metal Deposits Associated with Volcanic Environments in the Southwest: In Relations of Tectonics to Ore Deposits in the Southern Cordillera. Geological Society of Arizona, Digest 14, 237-262.
Cole, D.R. & Drummond, S.E., 1986. The effect of transport and boiling on Ag/Au ratios in hydrothermal solutions: a preliminary assessment and possible implications for the formation of epithermal precious metal ore deposits. Journal of Geochemical Exploration 25, 45-79.
Davis, C., 1986. Statistics and Data Analysis in Geology. John Wiley & Sons, New York. 640 pp.
Dreier, J.E., 2005. The Environment of vein Formation and Ore Deposition in the Purisima-Colon Vein System, Pachuca Real del Monte District, Hidalgo, Mexico. Economic Geology 100, 1325 - 1347.
Grancea, L., Bailey, L., Leroy, J., Banks, D., Marcoux, E., Milési, J.P., Cuney, M., André, A.S., Istvan, D. & Fabre, C., 2002. Fluid evolution in the Baia Mare epithermal gold/polymetallic district, Inner Carpathians, Romani. Mineral Deposita 37, 630-647.
Hedenquist, J.W., Arribas, A.R. & Gonzalez-Urien, E., 2000. Exploration for epithermal gold deposits. Reviews in Economic Geology 13, 245-277.
Henley, R.W., Brown, K.L., 1985. A practical guide to the thermodynamics of geothermal fluids and hydrothermal ore deposits. Reviews in Economic Geology 2, 25-44.
Howarth, R.I., 1993. Statistics and Data Analysis in Geochimical Prospecting. [In:] G.J.S, Govett (Ed). Handbook of Exploration Geochemistry. Elsever, Amsterdam. 2, 44-75.
Krauskopf, K.B., 1979. Introduction to geochemistry. 2nd ed. McGraw-Hill Kogakushu, New York. 617pp.
McLemore, V.T., 2008. Geochemistry and statistical analyses of epithermal veins at the Carlisle and Center mines, Steeple Rock District. New Mexico, USA. Arizona Geological Society Digest 22, 485-496.
Nabavi, M., 1976. An Introduction to the Geology of Iran. Geological Society of Iran, Teheran. (in Persian). 109 pp.
Nie, N.H., Hull, C.H. & Jenkins, J.G., Steinbrenner, K. & Bent, P.H., 1975. Statistical package for the Social Sciences. McGraw-Hill Book Co, New York, 675 pp.
Pokrovski, G.S., Borisova, Yu.A. & Harrichoury, J.C., 2008. The effect of sulfur on vapor- liquid fractionation of metals in hydrothermal systems. Earth and Planetary Science Letters 266, 345-362.
Radmard, K., Zamanian, H., Hosseinzadeh, M.R. & Ahmadi Khalaj, A., 2017. Geochemistry and hydrothermal evolution of the Mazraeh Shadi-Hizehjan precious and base metal deposit, northeastern Tabriz, Iran. Journal of Mineralogy and Geochemistry 194-3, 227-250.
Rassi, R. & Afzal, P., 2015. Correlation between Au Lithogeochemical Anomalies and Fault-density using Geostatistical and Fractal Modeling in Sharaf Abad-Hizehjan Area, NW Iran. Universal Journal of Geoscience 3, 51-58.
Sillitoe, R.H., 1999. Styles of high-sulfidation gold, silver and copper mineralization in porphyry and epithermal environments. [In:] Weber, G. (Ed.): Pacrim ’99 Congress, Bali, Indonesia. Proceedings. Australasian Institute of Mining and Metallurgy, Parkville, 29-44.
Sillitoe, R.H. & Hedenquist, J.W., 2003. Linkage between volcanotectonic settings, ore-fluid compositions, and epithermal precious- metal deposits. Society of Economic Geologist, Special Publication 10, 315-343.
Simmons, S.F. & Browne, P.R.L., 2000. Hydrothermal minerals and precious metals in the Broadlands-Ohaaki geothermal system: Implications for understanding low-sulfidation epithermal environments. Economic Geology 95, 971-999.
Tuysuz, N. & Yaylali, G., 2005. Geostatistics. Karadenis Technical University Publication 220, 400 pp.
License
Copyright (c) 2017 Kaikhosrov Radmard, Hassan Zamanian, Mohamad Reza Hosseinzadeh, Ahmad Ahmadi Khalaji
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 Unported License.