Sagh iron oxide Cu-Ag±Au mineral occurrence, SE of Torbat-e-Heydarieh: evidence of Geology, mineralization, geochemistry and fluid inclusion

Document Type : Research Article

Authors

1 M.Sc. student, Department of Geology, Faculty of Science, Ferdowsi University of Mashhad, Mashhad, Iran

2 Professor, Department of Geology and Research Center for Ore Deposits of Eastern Iran, Faculty of Science, Ferdowsi University of Mashhad, Mashhad, Iran

3 Professor, Department of Geology, Faculty of Science, Ferdowsi University of Mashhad, Mashhad, Iran

Abstract

Sagh mineral occurrence is located southeast of Torbat-e-Heydarieh, Khorasan Razavi province, and in the eastern part of the Khaf-Kashmar-Bardeskan magmatic belt. The rock units of area are divided into two categories: intrusions (monzonite, monzodiorite, diorite, and syenite) in the southern half, and conglomerate in the northern half. One square kilometer of continuous mineralization may be observed as stockwork, while there are other locations where it has a linear trend and is supported by intrusive rocks. Primary minerals include specularite, chalcopyrite, pyrite, galena, and sulfosalt, and secondary minerals include malachite, goethite, hematite, chalcosite, caveolite, and anglesite. The mineralization textures are vein-veinlet, disseminated, replacement, and cloform, mainly with a strong chloritic-silicified alteration. The average amount of copper is 0.8 with a maximum of more than 3%, the average amount of silver is 24.4 with a maximum of more than 113 ppm, and the average amount of gold is 44 with a maximum of 250 ppb. The average amount of lead is 761 ppm with a maximum of 0.4% and the average amount of zinc is 430 ppm with a maximum of 0.1%. The formation temperature of ore-forming fluid is between 159 and 328 °C and the salinity is between 7.2 and 16.7 wt.% equiv. NaCl. The mixing of magmatic fluids with meteoric waters with low temperatures and salinity was the most important mechanism of mineral formation. Based on the evidence of tectonic setting, lithology, type of alteration, shape, and state of mineralization, and the presence of abundant specularity with copper, silver, and gold anomalies, probably the Sagh area is iron oxide Cu-Ag±Au type.
 
Introduction
The geological settings, hydrothermal alteration, and mineralizing fluid compositions vary among the deposits of “IOCG-type” (Hitzman et al., 1992; Sillitoe, 2003). However, they belong to a family of Cu ±Au deposits that include substantial hydrothermal alkali (Na/Ca/K) alteration and a lot of low-Ti iron oxide (magnetite and/or hematite). According to Williams et al. (2005), these deposits likewise exhibit strong structural constraints and a temporal but not a tight geographical relationship with igneous rocks. They formed in rift or subduction settings (Hitzman, 2002) from the Late Archean to the Pliocene (Groves et al., 2010).
Sagh mineral occurrence is located the southeast of Torbat-e-Heydarieh, Khorasan Razavi province, and in the eastern part of the Khaf-Kashmar-Bardeskan magmatic belt (Fig.1). This belt has a high potential for iron oxide copper-gold type deposits and sometimes skarn and porphyry copper (Karimpour, 2004).
The purpose of this research is geological studies and determine the relationship of intrusions with mineralization, examine the total paragenesis sequence, geochemistry, fluid inclusions studies and finally determine the mineralization model, and the formation of mineral occurrences in the Sagh area, for the first time is done.
 
Materials and methods
To investigate the lithology, alteration, and mineralization of the Sagh area, 61 samples were taken mainly from the intrusions. 32 samples for the thin section and 10 samples for the polished thin section and polished block were selected, prepared, and studied. Then, the geological and alteration-mineralization map with a scale of 1:5000 was prepared in Arc GIS software. Furthermore, for geochemical studies of mineralization zones and veins, 24 samples were taken and sent to the Zarazma laboratory for analysis. Analysis was done by the ICP-OES method. Furthermore, 11 samples were selected for gold analysis with Fire assay, and sent to Zarazma laboratory. Using a cooling and heating system made by Linkam Company, model THM 600, microthermometric tests and salinity determination were performed on 2 wafers of quartz minerals and 31 fluid inclusions at Ferdowsi University of Mashhad.
 
Result
The rock units of the area are divided into two categories: subvolcanic and plutonic intrusions in the southern half and conglomerate units in the northern half. Intrusive rocks are composed of monzonite, monzodiorite, diorite and syenite. Mineralization can be seen in the form of stockwork in a wide and continuous zone with an area of about one square kilometer, but in some places, it has a linear trend (NE-SW and NW-SE trend) which is hosted by intrusive rocks. Primary minerals include specularite, chalcopyrite, pyrite, galena, and sulfosalt, and secondary minerals include malachite, goethite, hematite, chalcosite, covellite, and anglesite. Vein-veinlet, disseminated, replacement, and cloform mineralization textures are seen, with a dominant chloritic-silicified alteration. The average concentration of copper is 0.8%, with a maximum concentration of more than 3%, silver is 24.4 ppm, with a maximum concentration of more than 113 ppm, and gold is 44 ppb, with a maximum concentration of more than 250 ppb, according to geochemical data. The average amount of lead is 761 ppm with a maximum of 0.4% and the average amount of zinc is 430 ppm with a maximum of 0.1%. Based on fluid inclusions studies, the formation temperature of ore-forming fluid is between 159 and 328 °C, and the salinity is between 7.2 and 16.7 wt.% equiv. NaCl.
 
Discussion and Conclusion
Comparing the characteristics of Sagh prospect area with other copper-bearing deposits shows that this area is very similar to iron oxide copper-gold deposits. An empiric definition of IOCG deposits is summarized as having the following five characteristics (Williams et al., 2005): (1) copper, with or without gold, as economic metals, (2) hydrothermal ore styles and strong structural controls, (3) abundant magnetite and/or hematite, (4) Fe oxides with Fe/Ti ratios greater than those in most igneous rocks and bulk crust, and (5) no clear spatial associations with igneous intrusions as, for example, displayed by porphyry and skarn ore deposits.
Sillitoe (2003) proposed a close genetic relationship between IOCG deposits in northern Chile, and dioritic plutons. Mineralization in the Sagh area has a close relationship with monzonitic, monzodiorite, and diorite, which are similar to Kuh-e-Zar, Bahariyeh, Namaq, Fadiheh, Chenar, and other KKBMB deposits (Table 3).
The main alteration related to mineralization in the Sagh is propylitic-silicified, and its propylitic alteration is characterized by chlorite mineral. Extensive chlorite alteration in the Sagh area is similar to Monteverde deposit in Peru (Vila et al., 1998), Mont-del-Aigle in Canada (Simard et al., 2006), Kuh-e-Zar Tarbat Heydarieh (Karimpour et al., 2017), and other IOCG type deposits in the KKBMB belt (Almasi et al., 2015; Taghadosi and Malekzadeh Shafaroudi, 2018; Najmi et al., 2023; Sahebi Khader et al., 2021; Behnamnia et al., 2023) and Qala Zari (Karimpour, 2005) in the Lut block, where the temperature and salinity of ore-fluid are lower than some IOCG type deposits in the world.
Based on the available evidence, the mineral occurrence of the Sagh includes 1) the presence of oxidant intrusions formed in the subduction zone in the KKBMB, 2) mineral paragenesis of specularity, chalcopyrite, pyrite, and galena, 3) structural control of mineralization, 4) copper, silver, gold, and lead geochemical anomaly, 5) chloritic-silicified alteration, which is very compatible with iron oxide copper-silver-gold systems. The location of this area in the KKBMB belt, which has great potential for IOCG deposits, and near other IOCG deposits that have many similarities (Almasi et al., 2015; Karimpour et al., 2017; Sahebi Khader et al., 2021; Najmi et al., 2023), is a confirmation of this claim.
Although monzonitic, monzodiorite, diorite, and syenitic intrusions are the host rock of mineralization and mineralization is controlled by structures and faults, this magmatism can be represented of source rock at deep. The mineral paragenesis of the Sagh and the abundance of specularity with sulphide minerals of copper, lead, and silver, which are associated with quartz and chlorite, show that mineralization generated from a high fO2, Fe-Si rich ore fluid.
The metal originated from an oxidan magmatism from deep, and moved up through faults, joints, and fractures. The mixing of magmatic ore solution with higher temperature and salinity with meteoric water with lower temperature and salinity has finally led to the deposition of sulfides, and the formation of mineralization. Temperature-salinity and alteration evidence show that we are currently in the upper parts of the system, and we need more information. The relevance of this magmatic belt in eastern Iran as a significant metallogenic zone for deposits of copper, gold, and silver is growing as more and more IOCG mineral occurrences are found there.

Keywords

References

Almasi, A., Karimpour, M.H., Ebrahimi Nasrabadi, Kh., Rahimi, B., KlÖtzli, U. and Santos, J.F., 2015. Geology, mineralization, U-Pb dating and Sr-Nd isotope geochemistry of intrusive bodies in northeast of Kashmar. Journal of Economic Geology, 7(1): 69–90. (in Persian with English abstract) https://doi.org/10.22067/econg.v7i1.44721
Barton, M.D. and Johnson, D.A., 1996. Evaporitic-source model for igneous-related Fe oxide–(REE–Cu–Au–U) mineralization. Geology, 24(3): 259–262. https://doi.org/10.1130/0091-7613(1996)024<0259:ESMFIR>2.3.CO;2
Beane, R.E., 1983. The Magmatic–Meteoric Transition. Geothermal Resources Council, Special Report 13, pp. 245–253.
Behnamnia, O., Malekzadeh Shafaroudi, A., Mazloumi Bajestani, A. and Hajimirzajan, H., 2023. Mineralization, geochemistry and fluid inclusion studies in the Chenar prospect area, east of Kashmar: Evidence of copper mineralization with iron oxide. Advanced Applied Geological Journl. In press. (in Persian with English abstract)
Chen, H., Kyser, T.K. and Clark, A.H., 2011. Contrasting fluids and reservoirs in the contiguous Marcona and Mina Justa iron oxide-Cu (-Ag-Au) deposits, south-central Perú. Mineralium Deposita, 46: 677–706. https://doi.org/10.1007/s00126-011-0343-x
Fan, H.R., Hu, F.F., Wilde, S.A., Yang, K.F. and Jin, C.W., 2011. The Qiyugou gold–bearing breccia pipes, Xiong’ershan region, central China: Fluid–inclusion and stable–isotope evidence for an origin from magmatic fluids. International Geology Reviews 53(1): 25–45. https://doi.org/10.1080/00206810902875370
Fournier, R.O., 1999. Hydrothermal processes related to movement of fluid from plastic into brittle rock in the magmatic-epithermal environment. Economic Geology, 94(8): 1193–1212. https://doi.org/10.2113/gsecongeo.94.8.1193
Golmohammadi, A., Karimpour, M.H., Malekzadeh Shafaroudi, A. and Mazaheri, S.A., 2014. Petrology and U-Pb zircon dating of intrusive rocks from A, C-south, and Dardvay districts, Sangan iron stone mine, Khaf. Journal of Economic Geology, 5(9): 155–174. (in Persian with English abstract) https://doi.org/10.22067/econg.v5i2.31716
Golmohammadi, A., Karimpour, M.H., Malekzadeh Shafaroudi, A. and Mazaheri, S.A., 2015. Alteration mineralization, and radiometric ages of the source pluton at the Sangan iron skarn deposit, northeastern Iran. Ore Geology Reviews, 65(2): 545–563. https://doi.org/10.1016/j.oregeorev.2014.07.005
Groves, D.I., Bierlein, F.P., Meinert, L.D. and Hitzman, M.W., 2010. Iron oxide copper–gold (IOCG) deposits through Earth history:implications for origin, lithospheric setting, and distinction fromother epigenetic iron oxide deposits. Economic Geology, 105(3): 641–654. https://doi.org/10.2113/gsecongeo.105.3.641
Gu, L.X., Wu, C.Z., Zhang, Z.Z., Franco, P., Ni, P., Chen, P.R. and Xiao, X.J., 2011. Comparative study of ore-forming fluids of hydrothermal copper-gold deposits in the lower Yangtze River Valley, China. International Geology Reviews, 53(5–6): 477–498. https://doi.org/10.1080/00206814.2010.533873
Haynes, D.W., Cross, K.C., Bills, R.T. and Reed, M.H., 1995. Olympic Dam ore genesis: a fluid-mixing model. Economic Geology, 90(2): 281–307. https://doi.org/10.2113/gsecongeo.90.2.281
Hitzman, M.W., 2002. Iron oxide-Cu–Au deposit: what, where, when, and why. In: T.M. Porter, (Editor), Hydrothermal Iron Oxide Copper-Gold And Related Deposits: a Global Perspective V1. PGC Publishing, Adelaide, pp. 9–26. Retrieved June 3–5, 2023 from https://books.google.com/books/about/Hydrothermal_Iron_Oxide_Copper_gold_Rela.html?id=NXPxAAAAMAAJ
Hitzman, M.W., Oreskes, N. and Einaudi, M.T., 1992. Geological characteristics and tectonic setting of Proterozoic iron oxide (Cu–U– Au–REE) deposits. Precambrian Research, 58(1–4): 241–287. https://doi.org/10.1016/0301-9268(92)90121-4
Hopper, D. and Correa, A., 2000. The Panulcillo and Teresa de Colmo copper deposits: two contrasting examples of Fe-ox-Cu-Au mineralisation from the Coastal Cordillera of Chile. In: T.M. Porter, (Editor), Hydrothermal iron oxide copper-gold and related deposits: A global perspective 2, PGC Publishing, Adelaide, 1: 177–189. Retrieved June 3–5, 2023 from https://www.geokniga.org/bookfiles/geokniga-14panulcillo-and-teresa-de-colmodhopper.pdf
Hossieni, R., Karimpour, M.H. and Malekzadeh Shafaroudi, A., 2018. Petrography, geochemistry, U-Pb dating and Sr-Nd isotopes of igneous rocks in Tannurjeh porphyry Au-Cu prospect area (NE Kashmar). Petrological Journal, 9(1): 45–70. (in Persian with English abstract) https://doi.org/10.22108/ijp.2017.82019.0
Injoque, E.J., 2002. Fe oxide-Cu-Au deposits in Peru: An integrated view. In: T.M. Porter, (Editor), Hydrothermal iron oxide copper-gold and related deposits. A global perspective 2, PGC Publishing, Adelaide, 2: 97–113. Retrieved June 3–5, 2023 from https://www.geokniga.org/bookfiles/geokniga-07iocg-peru.pdf
Karimpour, M.H., 2004. Mineralogy, Alteration, source rock, and tectonic setting of Iron–Oxides Cu–Au deposits and examples of Iran. 11th symposium of Iranian Crystallography and Mineralogy Society, Department of Geology, University of Yazad, Yazad, Iran, pp. 184–189. (in Persian with English abstract)
Karimpour, M.H., 2005. Comparison of Qaleh Zari Cu-Au-Ag deposit with other Iron Oxides Cu-Au (IOGC-type) deposits, a new classification. Iran. Iranian Journal of Crystallography and Mineralogy, 13(1): 167–184. Retrieved September 10, 2023 from https://ijcm.ir/article-1-734-en.html
Karimpour, M. H., Saadat, S. and Malekzadeh Shafaroudi, A., 2006. Geochemistry, petrology, and Mineralization of Tannurjeh porphyry gold-copper. Journal of Science (University of Tehran) (JSUT) 3(33): 173–185. (in Persian with English abstract)
Karimpour, M. H., Malekzadeh Shafaroudi, A., Mazloumi Bajestani, A., Keith Schader, R., Stern, Ch.R., Farmer, L. and Sadeghi, M., 2017. Geochemistry, geochronology, isotope and fluid inclusion studies of the Kuh-e-Zar deposit, Khaf-Kashmar-Bardaskan magmatic belt, NE Iran: Evidence of gold-rich iron oxide–copper–gold deposit. Journal of Geochemical Exploration, 183(Part A): 58–78. https://doi.org/10.1016/j.gexplo.2017.10.001
Lecumberri-Sanchez P., Steel-MacInnis M. and Bodnar R.J., 2012. A numerical model to estimate trapping conditions of fluid inclusions that homogenize by halite disappearance. Geochimica et Cosmochimica Acta, 92: 14–22. https://doi.org/10.1016/j.gca.2012.05.044
Malekzadeh Shafaroudi, A., Karimpour, M.H. and Golmohammadi, A., 2013. Zircon U–Pb geochronology and     petrology of intrusive rocks in the C-North and Baghak districts, Sangan iron mine, NE Iran. Journal of Asian Earth Sciences, 64: 256–271. https://doi.org/10.1016/j.jseaes.2012.12.028
Marschik, R. and Fontboté, L., 1998. Copper (–Iron) mineralization and superposition of alteration events in the Punta del Cobre belt, Northern Chile. In: F. Camus, R.H. Sillitoe, R. Peterson, (Editors), Andean copper deposits: new discoveries, mineralization, styles and metallogeny, Society of Economic Geology, Specific Publication, 5: 171–190. https://doi.org/10.5382/SP.05.12
Marschik, R. and Fontbot´e, L., 2001. The Candelaria-Punta del Cobre iron oxide Cu–Au–Zn–Ag deposits. Chile. Economic Geology, 96(8): 1799–1826. https://doi.org/10.2113/gsecongeo.96.8.1799  
Marschik, R., Fontignie, D., Chiaradia, M. and Voldet, P. 2003. Geochemical and Sr-Nd-Pb-O isotope composition of granitoids of the Early Cretaceous Copiaco plutonic complex (27° 30´S), Chile. Journal of South America Earth Sciences, 16(5): 381–398. https://doi.org/10.1016/S0895-9811(03)00104-4
Najmi, F., Malekzadeh Shafaroudi, A., Karimpour, M.H. and Simon, R.P., 2023, The Bahariyeh iron oxide copper–gold deposit, Khaf-Khashmar-Bardaskan magmatic belt, NE Iran: Constraints from geochemical, fluid inclusions, and O-S isotope studies. Ore Geology Reviews, 159: 105501. https://doi.org/10.1016/j.oregeorev.2023.105501
Oliver, N.H.S., Cleverley, J.S., Mark, G., Pollard, P.J., Fu, B., Marshall, L.J., Rubenach, M.J., Williams, P.J. and Baker, T., 2004. Modeling the role of sodic alteration in the genesis of iron–oxide–copper–gold deposits, eastern Mount Isa block, Australia. Economic Geology, 99(6): 1145–1176. https://doi.org/10.2113/gsecongeo.99.6.1145
Pollard, P.J., 2001. Sodic (-calcic) alteration in Fe–oxide–Cu–Au districts: an origin via unmixing of magmatic H2O–CO2– NaCl ± CaCl2–KCl fluids. Mineralum Deposita, 36: 93–100. https://doi.org/10.1007/s001260050289
Pollard, P.J., 2000. Evidence of a magmatic fluid and metal source for Fe-oxide Cu–Au mineralization. In: T.M.  Porter (Editor), Hydrothermal iron oxide copper–gold and related deposits: a global perspective 1, PGC Publishing, Adelaide, 1: 27–41. Retrieved June 3–5, 2023 from https://www.geokniga.org/bookfiles/geokniga-04magmatic-fluid-and-metal-sourcepjpollard.pdf
Roedder, E., 1984. Fluid inclusions. In: P.E. Ribbe (Editor), Reviews in Mineralogy 12. Mineralogy Society of America, 12:644 pp. Retrieved June 3–5, 2023 from https://www.scirp.org/(S(i43dyn45teexjx455qlt3d2q))/reference/ReferencesPapers.aspx?ReferenceID=1868459
Sahebi Khader, J., Malekzadeh Shafaroudi, A. and Mazloumi Bajestani, A., 2021. Mineralogy, structure and texture and geochemistry­ of Fadiheh Cu-Au mineral occurrence, northwestern Torbat Heydariyeh. Iranian Journal of Crystallography and Mineralogy, 30(1): 57–74. http://dx.doi.org/10.52547/ijcm.30.1.57
Shafaii Moghadam, H., Li, X-H., Ling, X-X., Santos, J.F., Stern, R.J., Li, Q. and Ghorbani, Gh., 2015. Eocene Kashmar granitoids (NE Iran): Petrogenetic constraints from U–Pb zircon geochronology and isotope geochemistry. Lithos, 216-617: 118-135. https://doi.org/10.1016/j.lithos.2014.12.012
Shepherd, T.J., Rankin, A.H. and Alderton, D.H.M., 1985. A practical guide to fluid inclusion studies. London, UK: Blackie. Press, London, 239 pp.
Sillitoe, R.M., 2003. Iron oxide-copper-gold deposits: An Andean view. Mineralum Deposita, 38: 787–812. https://doi.org/10.1007/s00126-003-0379-7
Simard, M., Beaudoin, G., Bernard, J. and Hupe, A., 2006. Metallogeny of the Mont-de-l’Aigle IOCG deposit, Gaspé Peninsula, Québec, Canada. Mineralum Deposita, 41: 607–636. https://doi.org/10.1007/s00126-006-0061-y
Steele-MacInnis, M., Lecumberri-Sanchez, P. and Bodnar, R.J., 2012. HOKIEFLINCS-H2O-NACL: A Microsoft Excel spreadsheet for interpreting microthermometric data from fluid inclusions based on the PVTX properties of H2O–NaCl. Computer in Geosciences, 49: 334–337. http://dx.doi.org/10.1016/j.cageo.2012.01.022
Taghadosi, H. and Malekzadeh Shafaroudi, A., 2018. Mineralogy, Alteration, geochemistry, and fluid inclusion studies of Fe oxide-copper mineralization of Namegh area, NE Kashmar. Iranian Journal of Crystallography and Mineralogy, 26(3): 541-554. (in Persian with English abstract) http://dx.doi.org/10.29252/ijcm.26.3.541
Vila, T., Lindsay, N. and Zamora, R., 1998. Geology of the Manto Verde copper deposit, northern Chile: a specularite-rich hydrothermal tectonic breccia related to the Atacama fault zone. In: F. Camus, R.H. Sillitoe, R. Petersen, (Editors), Andean copper deposits: new discoveries, mineralization, styles and metallogeny. Society of Economic Geology, Special Publication, 5: 157–170. https://doi.org/10.5382/SP.05.11
Whitney, D.L. and Evans, B.W., 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1): 185–187. https://doi.org/10.2138/am.2010.3371
Williams, P.J., Barton, M.D., Johnson, D.A., Fontboté, L., de Haller, A., Mark, G., Oliver, N.H.S. and Marschik, R., 2005. Iron oxide copper-gold deposits: Geology, Space-time distribution, and possible modes of origin. In: J.W. Hedenquist, J.F.H. Thompson, R.J. Goldfarb and J.P. Ricards (Editors), 100th Anniversary of Economic Geology, Society of Economic Geologists pp. 371–405. https://doi.org/10.5382/AV100.13
Yousefi, L., Haidarian Shahri, M.R. and Karimpour, M.H., 2008. Geology, mineralogy, fluid inclusion thermometry and ground magnetic of Shahrak Magnetite-Specularite Cu-Au prospecting area, Torbat-eHeydariyeh, Iran. Iranian Journal of Crystallography and Mineralogy, 16(3): 505–516. (in Persian with English abstract) Retrieved June 3, 2023 from http://ijcm.ir/article-1-631-en.html
Zhai, D.G., Liu, J.J., Wang, J.P., Yao, M.J., Wu, SH., Fu, C., Liu, Z.J., Wang, S.G. and Li, Y.X., 2013. Fluid evolution of the Jiawula Ag-Pb-Zn deposit, Inner Mongolia: mineralogical, fluid inclusion, and stable isotopic evidence. International Geology Reviews, 55(2): 204–224. https://doi.org/10.1080/00206814.2012.692905
Zhu, Z., 2016. Gold in iron oxide copper–gold deposits. Ore Geology Reviews, 72(Part 1): 37–42. https://doi.org/10.1016/j.oregeorev.2015.07.001
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  • Receive Date: 15 August 2023
  • Revise Date: 20 September 2023
  • Accept Date: 20 September 2023

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