Scientific Quarterly Journal of Geosciences

Scientific Quarterly Journal of Geosciences

Comparison of epithermal base and precious metal deposits in Gandy and Abolhassani districts, Semnan Province, Iran

Document Type : Original Research Paper

Authors
Gholamhosein Shamanian 1
Jamshid Hassanzadeh 2
Jeffrey W. Hedenquist 3
Keiko Httori 3
Majid Ghaderi 4
1 Department of Geology, University of Shahid Beheshti, Tehran, Iran
2 Department of Geology, University of Tehran, Tehran, Iran
3 Department of Earth Science, University of Ottawa, Ottawa, Ontario K1N 6N5, Canada
4 Department of Geology, University of Tarbiat Modarres, Tehran, Iran.
Abstract
Gandy and Abolhassani epithermal precious-and base-metal deposits occur in the Tertiary calc-alkaline volcanic belt of northeast Iran. The exposed rock units consist of a volcaniclastic sequence of thin-bedded siltstones and sandstones, lapilli tuffs, volcanic breccias and intermediate lava flows at Gandy, and mostly andesitic flows at Abolhassani.
Mineralization in Gandy occurs as veins and breccias and can be divided into three main stages. Stage I is economically important in terms of precious metal content.Stage II consists of four substages and contains the majority of base-metal mineralization. The final stage is dominated by quartz and calcite. Mineralization of the Abolhassani veins occurred in three main stages. The first two stages contain similar mineral assemblages, including quartz, calcite, galena, sphalerite, pyrite and chalcopyrite, which are economically important in terms of base-metal content, whereas the final stage is dominated by quartz and calcite.
The average homogenization temperatures and salinities of fluid inclusion assemblages from Gandy range from 234o to 285 oC, and 4.2 to 5.4 wt% NaCl equiv. The homogenization temperatures are in a good agreement with isotopic temperatures from two sphalerite and galena pairs (236o and 245 oC). The average temperature and salinity of fluid inclusion assemblages from Abolhassani district range from 234o to 340 oC, and 6.7 to 18.7 wt% NaCl equiv. Sulfide pairs of sphalerite-galena do not give reasonable equilibration fractionation temperatures at Abolhassani. Comparison of Th versus freezing (TmI) values for the two deposits indicates the presence of a moderate salinity fluid (5-6 wt% NaCl) of similar temperature (250 oC) in each deposit, but with a higher salinity component also present at Abolhassani. The Abolhassani district shows higher average Ag/Au (34.7) and Pb + Zn contents (up to 7.6 wt%) than Gandy (Ag/Au 2.1 and 3.9 wt%), consistent with the nearly 4x higher maximum salinity at Abolhassani compared to Gandy.
Precious and base-metal mineralization within hydrothermal breccias of Gandy may have deposited under boiling conditions, whereas base-metal mineralization in stage II most likely occurred due to dilution. Based on mixing trends, base-metal sulfides in Abolhassani veins were deposited during periodic injection and dilution of brines. The minimum depth of formation was at least 430 m and 600 m below the paleowater table for Gandy and Abolhassani, respectively.
Keywords
Gandy
Abolhassani
Precious- and base- minerals
Epithermal

Subjects

Albinson, T., Norman, D.I., Cole, D.& Chomiak, B., 2001- Controls on formation of low-sulfidation epithermal deposits in Mexico: Constrains from fluid inclusion and stable isotope data: Society of Economic Geologists, Special Publication 8, p. 1-32.
Benning, L.G.& Seward, T.M., 1996- Hydrosulfide complexing of Au(I) in hydrothermal solutions from 150 to 400 oC and 500 to 1500 bars: Geochimica et Cosmochimica Acta, v. 60, p. 1849-1871.  
Bodnar, R.J., 1993- Revised equation and table for determining the freezing point depression of H2O-NaCl solutions: Geochimica et Cosmochimica Acta, v. 57, p. 683-684.
Bodnar, R.J., Reynolds, T.J.& Kuehn, C.A., 1985- Fluid inclusion systematics in epithermal systems: Reviews in Economic Geology, v. 2, p. 73-97.   
Buchanan, L.J., 1981- Precious metal deposits associated with volcanic environments in the Southwest: In W.R. Dickson and W.D. Payne, eds.,  Relations of Tectonics to Ore Deposits in the Southern Cordillera, Arizona Geol. Soc. Digest 14, pp. 237-262.
Camprubi, A., Canals, A., Cardellach, E., Prol-Ledesma, R.M.& Rivera, R., 2001- The La Guitarra, Ag-Au low sulfidation epithermal deposit, Temascaltepec district, Mexico: Vein structure, Mineralogy, and Sulfide-Sulfate Chemistry, Society of Economic Geologist Special Publication 8, p. 133-138.
Collins, P.L.F., 1979- Gas hydrate in CO2-bearing fluid inclusions and the use of freezing data for estimation of salinity: Economic Geology, v. 74, p. 1435-1444.
Geological Survey of Iran, 1995- Explanatory text of geochemical map of Moaleman (6960), Report no. 9, v. 1, 33 p.
Giggenbach, W.F.& Stewart, M.K., 1982- Processes controlling the isotopic composition of steam and water discharges from steam vents and steam-heated pools in geothermal areas: Geothermics, v. 11, p. 71-80.
Goldstein, R.H.& Reynolds, T.J., 1994- Systematics of fluid inclusions in diagenetic minerals: Society of Economic Paleontologists and Mineralogists Short Course 31, 199 p.
Haas, J.L., Jr., 1971- The effect of salinity on the maximum thermal gradient of a hydrothermal system at hydrostatic pressure: Economic Geology, v. 66, p. 940-946.
Hedenquist, J.W.& Henley, R.W., 1985- Effect of CO2 on freezing point depression measurements of fluid inclusions: Evidence from active systems and application to epithermal studies: Economic Geology, v. 80, p. 1379-1406.
Hedenquist, J.W., Reyes, A.G., Simmons, S.F.& Taguchi, S., 1992- The thermal and geochemical structure of geothermal and epithermal systems: A framework for interpreting fluid inclusion data: European Journal of Mineralogy, v. 4, p. 989-1015. 
Hedenquist, J.W., Arribas R., A.& Gonzalez-Urien, E, 2000- Exploration for epithermal gold deposits: Reviews in Economic Geology, v. 13, p. 245-277.
Henley, R.W., 1985- The geothermal framework of epithermal deposits: Society of Economic Geologist, Reviews in Economic Geology, v. 2, p. 1-24.
Ohmoto, H.& Goldhaber, M.B., 1997- Sulfur and carbon isotopes: Barnes, H.L., ed., Geochemistry of hydrothermal ore deposits, 3 rd edition, New York, John Wiley and Sons, p. 517-611.   
Roedder, E., 1984- Fluid inclusions: Reviews in Mineralogy, v. 12, 644 p. 
Seward, T.M.& Barnes, H.L., 1997- Metal transport by hydrothermal ore fluids: In Barnes, H.L., ed., Geochemistry of hydrothermal ore deposits, 3rd edition, New York, John Wiley and Sons.   
Simmons, S.F., 1991- Hydrothermal implications of alteration and fluid inclusion studies in the Fresnillo district, Mexico: Evidence for a brine reservoir and a descending water table during the formation of hydrothermal Ag-Pb-Zn orebodies: Economic Geology, v. 86, p. 1579-1601.
Simmons, S.F., 1995- Magmatic contributions to low-sulfidation epithermal deposits: Mineralogical Association of Canada Short Course, v. 23, p. 455-477.
Simmons, S.F., Gemmell, B.& Sawkins, F.J., 1988- The Santo Nino silver-lead-zinc vein, Fresnillo District, Zacatecas, Mexico: Part II. Physical and chemical nature of ore-forming solutions: Economic Geology, v.83, p. 1619-1641. 
White, N.C.& Hedenquist, J.W., 1990- Epithermal environments and styles of mineralization: Variations and their causes and guidelines for exploration: Journal of Geological Exploration, v. 36, p. 445- 474.
Scientific Quarterly Journal of Geosciences
Volume 14, Issue 53
Autumn 2004, Vol. 14, No. 53
Autumn 2004
Pages 100-117