Formation and evolution stages of gold rich Barika massive sulfide deposit, east of Sardasht, northern Sanandaj-Sirjan zone: based on structural, textural and fluid inclusion studies

Document Type : Research Article

Authors

1 Tarbiat Modares

2 Kharazmi

Abstract

Barika gold (and silver) rich massive sulfide deposit is located 18 km east of Sardasht, north western part of Sanandaj-Sirjan metamorphic zone. Rock units outcropped in this area are Cretaceous metamorphosed volcano-sedimentary rocks in green schist facies, and include association of meta-andesite, meta-tuffite, phyllite and slate rocks, where the meta-andesitic unit (Kmv1) is host rock to the deposit. Barika deposit is composed of stratiform ore and stringer zone. Stratiform part contains massive and banded sulfide and barite associated with subordinary silica bands underlain by stringer silicic zone. The massive and banded ore is surrounded by an extensive zone of silicic stringer veins and disseminated mineralization within strongly altered and deformed andesitic volcanic rocks. Ore mineral assemblages in stratiform part of the deposit are quite variable and consist of pyrite, sphalerite, galena, stibnite, a variety of sulfosalt minerals and gold (electrum). Ore mineral assemblages in silicic veins in the stringer zone are simpler and consist of pyrite, galena, sphalerite, tetrahedrrite and trace chalcopyrite. Average gold and silver grades in stratiform ore are 8.3 and 420 g/t respectively and in silicic stringer veins are 0.7 and 30 g/t. Base metal content in both parts of the deposit are less than 1%. Based on our research, Barika is an immature Kuroko type massive sulfide deposit, which contains only black ore. The Barika deposit underwent low-grade metamorphism and high grade deformation after the ore deposition event. Geologic processes appear to control the mode of occurrence of gold in the deposit. In synvolcanism stage, deposition of a gold–bearing low temperature (140-200°C) and low salinity (1-9.6 wt% NaCl) hydrothermal fluid formed a Kuroko black ore type deposit. In the stage of mineralization, invisible gold was concentrated in framboidal pyrite and other sulfide minerals. The main effect of progressive metamorphism (D1) on gold mineralization is recrystallization of the framboidal pyrite and migration of submicroscopic gold to the crystal boundary to form electrum under low to moderate strain. Highly strain and deformation (D2) on the deposit caused the remobilization of gold and accompanied َAs, Sb, Ag, and Pb minerals and continued to form coarse-grained electrum (up to 3 mm) in open space fractures. The formation of barren silica veins (D3) and high angle normal faults (D4) are the results of retrograde metamorphism.

Keywords

References

[1] Poulsen K.H., Hannington, M.D., "Volcanic-associated massive sulphide gold", in Eckstrand, O.R., Sinclair, W.D., and Thorpe, R.I., eds., "Geology of Canadian mineral deposit types", Geology of Canada, vol, (1996) 183-196.
[2] Hannington M.D., Poulsen K.H., Thompson J.F.H., Sillitoe R.H. "Volcanogenic gold in massive sulfide environment: Reviews in Economic Geology",(1999) 325-356.
[3] Poulsen K.H., Robert F., Dube B., "Geological Classification of Canadian Gold Deposits", Geological Survey of Canada Bulletin،,( 2000) 540, 106 .
[4] Dube B., Gosselin P., Mercier-Langevin P., Hannington M., Galley A,"Gold-rich volcanogenic massive sulphide deposits, in Goodfellow", W.D., ed.,"Mineral deposits of Canada—A synthesis of major deposit-types, district metallogeny, the evolution of geological provinces, and exploration methods: Geological Association of Canada", Mineral Deposits Division, Special Publication no,( 2007) 75–94.
]5 [تاج الدین ح.، " گزارش اکتشاف ذخیره جدید طلای باریکا ( خاور سردشت ). سازمان زمین شناسی و اکتشافات معدنی کشور"، (1382).
]6 [یارمحمدی ع.،کانی شناسی، ژئوشیمی،" ساخت و بافت و ژنز کانه زائی طلا (نقره،فلزات پایه و باریت) در محدوده معدنی باریکا، شرق سردشت"، پایان نامه کارشناسی ارشد، دانشکده علوم پایه، دانشگاه تربیت مدرس،(١٣٨5).
[7] Large R.R., Huston D.L., McGoldrick P.J., Ruxton P.A., "Gold distribution and genesis in Australian volcanogenic massive sulfide deposits and their significance for gold transport models. Econ. Geol. Mon,(1989) 520-563
[8] Huston D.L." Gold in volcanic-hosted massive sulfide deposits; distribution, genesis, and exploration", in Hagemann, S.G. ed," Gold in 2000: Reviews in Economic Geology", ( 2000) 401-426.
]9 [یارمحمدی، ع.، راستاد، ا.، محجل، م.، شمسا، م.ج.، رخداد طلای باریکا: کانه زایی تیپ ماسیوسولفید ولکانوژنیک غنی از طلا در ایران، خلاصه مقالات بیست و چهارمین گردهمایی علوم زمین، سازمان زمین شناسی و اکتشافات معدنی کشور (1384).
[10] Mohajjel M., Fergusson C.L., Sahandi M.R. "Cretaceous–Tertiary convergence and continental collision, Sanandaj–Sirjan Zone, western Iran. J. Asian Earth Sci". 21(2003) 397–412.
[11] Azizi H., Jahangiri A." Cretaceous subduction-related volcanism in the northern Sanandaj-Sirjan Zone, Iran. J. Geodyn", 45 (2008) 178–190
[12] Azizi, H., Moinevaziri, H." Review of the tectonic setting of Cretaceous to Quaternary volcanism in northwestern Iran. J. Geodyn". 47(2008) 167–179.
[13] Ramboz C, Charef A , " Temperature, pressure, burial history, and paleohydrology of the Les Malines Pb-Zn deposit: reconstruction from aqueous inclusions in Barite in Econ. Geol", 83(1988)784-800.
[14] Larson L.T., Miller J.D., Nadeau J.E., Roedder E."Two sources of error in low temperature inclusion homogenization determination, and corrections on published
temperatures for the East Tennessee and Laisvall deposits. Economic Geology", 68(1973) 113–116
[15] Ullrich m. R. Bodnar R. J." Systematics of stretching of fluid inclusions. II. Barite at one atmosphere confining pressure, Economic Geology", 83(1988) 1037-1.
[16] Bodnar R. J. Bethke P. M. " Systematics of stretching of fluid inclusions. I fluorite and sphalerite at 1 atmosphere confining pressure, Economic Geology", 79(1984) 141-161
[17] Roedder E," Fluid inclusions. Reviews in Mineralogy", 12(1984) 644.
[18] Shepherd TJ, Rankin AH, Alderton DHM, "A Practical Guide to Fluid Inclusion Studies. Blackie, Glasgow", (1985) 239.
[19] Pisutha – Arnond, V. Ohmoto H. "Thermal history and chemical and isotopic compositions of the ore – forming fluids responsible for the Kuroko massive sulfide deposits in the Hokuroko district of Japan. Econ. Geol., Monogr", 5(1983) 198-223.
]20 [یارمحمدی ع.، راستاد ا.، محجل م.، شمسا م.ج.،.رخداد طلای باریکا،" کانه زایی تیپ ماسیوسولفید ولکانوژنیک غنی از طلا در ایران"، مجله علوم دانشگاه تهران. جلد 34، شماره 1، صفحات 47-60،.( ١٣٨7).
[21] Ohomot H., Mizukami M., Drummond S.E., Eldridge, C.S., Pisutha – Arnond, V. and Lenagh, T.C. "Chemical processes of Kuroko formation. Economic Geology, Monogr",5(1983) 570-604
[22] Ohmoto H. " Formation of volcanogenic massive sulfide deposits: the Kuroko perspective. Ore geology reviews", 10 (1996)135-177.
[23] Eldridge C.S., Barton P. B., Jr. Ohmoto H," Mineral textures and their bearing on formation of the Kuroko ore bodies. Economic Geology., Monogr".5(1983) 241-281
[24] Solomon M., Tornos F., Large R.R., Badham, J.N.P., Both, R.A., and Zaw, K. "Zn–Pb–Cu volcanic-hosted massive sulphide deposits: criteria for distinguishing brine pool-type from black smoker-type sulphide depo sition. Ore Geology Reviews 25"( 2004) 259–283.
[25] Huston D.L., Large R.R." A chemical model for the concentration of gold in volcanogenic massive sulfide deposits. Ore Geol. Rev.4".(1989) 171-200
[26] Hannington M.D., Peter J.M., Scott S.D." Gold in sea – floor polymetallic sulfides: Economic Geology", V.81,(1867-1883).
[27] Huston D., Large R, "Genetic and Exploration Significanco ef the Zinc Ratio (100 Zn/(Zn + Pb)) in Massive Sulfide Systems. Economic Geology", Vol. 82, (1987) 1521-1539
[28] Huston D., Bottrill R.S., Creelman R., Khin Zaw Ramsden T., Rand S., Gemmell J.B., Bruce L., Sie S.H., Large R.R, "Geologic and Geochemical Controls on the Mineralogy and Grain Size of Gold-Bearing Phases, Eastern Australian Volcanic Hosted Massive Sulfide Deposits". Econ.Geol,( 1992)87:542-563.
[29]Cox D, Rytuba J.J Lihir Island gold,"Geological survey Bulletin 1643U.S.Gological survey open-file Reporrt, (1987)87-272a.
[30] Galley A. G., Jonasson I. R., Franklin J. M., Gibson H. L., " Volcanogenic Massive Sulfide Deposits", in Hedenquist, J. W., Thompson, J. F. H., Goldfarb, R. J., and Richards, J. P., eds., Economic Geology 100th Anniversary Volume", Littleton, CO, "Society of Economic Geologists",(2005)523-560.
Send comment about this article
CAPTCHA Image

Files

Share

How to cite

Statistics