Geochemistry and tectonomagatic setting of Tertiary volcanic rocks of the Kangan area, northeast of Sarbisheh, southern Khorasan

Document Type : Research Article

Authors

1 Birjand

2 University of Birjand

Abstract

Introduction
The study area is located 12km away from the north east of Sarbisheh at the eastern border of the Lut block (Karimpour et al., 2011; Richards et al., 2012). The magmatic activity in the Lut blockhas begun in the middle Jurassic (165-162 Ma) and reached its peak in the Tertiary age (Jung et al., 1983; Karimpour et al., 2011). Volcanic and subvolcanic rocks in the Tertiary age cover over half of the Lut block with up to 2000 m thickness and they were formed due to subduction prior to the collision of the Arabian and Asian plates (Jung et al., 1983; Karimpour et al., 2011).
In the Kangan area, the basaltic lavas cropped out beyond the above intermediate to acid volcanic rocks. In this area, bentonite and perlite deposits have an economic importance. The main purpose of this paper is to present a better understanding of the tectono-magmatic settings of volcanic rocks in the northeast of Sarbisheh, east of Iran based on their geochemical characteristics.

Materials and methods
Fifteen samples were analyzed for major elements by inductively coupled plasma (ICP) technologies and trace elements by using inductively coupled plasma mass spectrometry (ICP-MS), following a lithium metaborate/tetraborate fusion and nitric acid total digestion, at the Acme laboratories, Vancouver, Canada.

Results
The Kangan area is located at the northeast of Sarbishe, Southern Khorasan and the eastern border of the Lut block. In this area, basaltic lavas have cropped out above intermediate to acid lavas such as andesite, dacite, rhyolite (sometimes perlitic) .The main minerals in the basalt are plagioclase, olivine and pyroxene, in andesite contain plagioclase, pyroxene, biotite and amphibole and in acid rocks include plagioclase, quartz, sanidine, biotite and amphibole. Intermediate to acid rocks have medium to high-K calc-alkaline nature and basalt is alkaline. Enrichment in LREE relative to HREE (Ce/Yb= 21.14-28.7), high ratio of Zr/Y(4.79- 10.81), enrichment in LILE and negative anomaly of Eu, Nb, P, Ti, Ba and Sr in intermediate to acid lavas are characteristics of subduction related calc-alkaline magmatism. Geochemical characteristics such as high ratio of La/Yb (8.18), low content of Rb with tectonic setting discriminant diagrams show within plate environment for basalt. The constituent magma of the studied rocks originated from an enriched garnet lherzolite source in 100 to 110km depth.

Discussion
Enrichment in LREE relative to HREE (Ce/Yb= 21.14-28.7), high ratio of Zr/Y (4.79- 10.81), enrichment in LILE and negative anomaly of Eu, Nb, P, Ti, Ba and Sr in intermediate to acid lavas are characteristics of subduction related calc-alkaline magmatism. Tectonic setting discrimination diagrams show that andesite to dacitic rocks are located in active continental margin (Schandle and Gorton, 2002) and basalt is placed within the volcanic plate zone and continental rift type (Verma et al., 2006). Intermediate to acid rocks of Kangan area originated from lithospheric mantle (Moharami et al., 2014) that is enriched by sediment melt related metasomatism (Ersoy et al., 2010) whereas Kangan basaltic lava origin is Nb enriched (Wang et al., 2008; Sajona et al., 1996) mixed lithospheric - asthenospheric mantle (Moharamiet al., 2014). According to the trace elements diagrams (Ellam, 1992), partial melting depth for generation of Kangan area lavas was determined to be about 100 to 110Km. Because of absent crustal contamination instances in the basalt, it can be argued that ascending of magma has been rapid and probably similar to other alkali basalts in east of Iran, it may be related to deep fault systems.

Acknowledgements
The authors would like to thank the reviewers for their constructive comments which greatly contributed to the improvement of the manuscript.

References
Ellam, R.M., 1992. Lithospheric thickness as a control on basalt geochemistry. Geology, 20(2): 153-156.
Ersoy, E.Y., Helvaci, C. and Palmer, M.R., 2010. Mantle source characteristics and melting models for the early-middle Miocene mafic volcanism in western Anatolia: implications for enrichment processes of mantle lithosphere and origin of K-rich volcanism in post-collisional settings. Journal of Volcanology and Geothermal Research, 198(1-2): 112-128.
Jung, D., Keller, J., Khorasani, R., Marcks, C., Baumann, A. and Horn, P., 1983. Petrology of the Tertiary magmatic activity the northern Lut area, East of Iran. Geological Survey of Iran, Tehran, Report 51, 519 pp.
Karimpour, M.H., Stern, C.R., Farmer, L., Saadat, S. and Malekezadeh, A., 2011. Review of age, Rb-Sr geochemistry and petrogenesis of Jurassic to Quaternary igneous rocks in Lut block, eastern Iran. Geopersia, 1(1):19-36.
Moharami, F., Azadi, I., Mirmohamadi, M., Mehdipour Ghazi, J. and Rahgoshay, M., 2014. Petrological and Geodynamical Constraints of Chaldoran Basaltic Rocks, NW Iran: Evidence from Geochemical Characteris. Iranian Journal of Earth Sciences, 6(1): 31-43.
Richards, J.P., Spell, T., Rameh, E., Razique, A. and Fletcher, T., 2012. High Sr/Y magmas reflect arc maturity, high magmatic water content, and porphyry Cu ± Mo ± Au potential: examples from the Tethyan arcs of central and eastern Iran and western Pakistan. Economic Geology, 107(2): 295–332.
Sajona, F.G., Maury, R.C., Bellon, H., Cotton, J. and Defant, M., 1996. High field strength element enrichment of Pliocene-Pelistocene island arc basalts, Zomboanga Peninsula, Western Mindanao Philippines. Journal of Petrology, 37(3): 693–726.
Schandl, E.S. and Gorton, M.P., 2002. Application of high field strength elements to discriminate tectonic setting in VMS environment. Economic Geology, 97(3): 629-642.
Verma, S.P., Guevara, M. and Agrawal, S., 2006. Discriminating four tectonic settings: Five new geochemical diagrams for basic and ultrabasic volcanic rocks based on log- ratio transformation of major-element data. Journal of Earth System Science, 115(5): 485-528.
Wang, Q., Wyman, D.A., Xu, J., Wan, Y., Li, C., Zi, F., Jiang, Z., Qiu, H., Chu, Z., Zhao, Z. and Dong, Y., 2008. Triassic Nb-enriched basalts, magnesian andesites, and adakites of the Qiangtang terrane (Central Tibet): evidence for metasomatism by slab-derived melts in the mantle wedge. Contributions to Mineralogy and Petrology, 155(4): 437-490.

Keywords

References

Afsharharb, A., Aghanabati, A. and Majdi, B., 1987. Geological map of Mashhad, scale 1:250000. Geological Survey of Iran.
Ajayebi, K.S., Karimpour, M.H., Mazaheri, S.A. and Saadat, S., 2009. Nature of fluid inclusions of Calc alkaline of Cu-Au mineralization from Tanourjeh area (North of Kashmar). Iranian Journal of Geology, 8(8): 55-69.
Alaminia, Z., Karimpour, M.H., Homam, S.M. and Finger, F., 2013. The magmatic record in the Arghash region (northeast Iran) and tectonic implications. International Journal of Earth Sciences, 3(12):103-118.
Almasi, A., Karimpour, M.H., Ebrahimi Nasrabadi, Kh., Rahimi, B. and KlÖtzli, U, 2016. Geology and geochemistry of sub-volcanic and plutonic bodies of Kashmar (North of Lut Block). Iranian Journal of Crystallography and Mineralogy, 24 (3): 539-556. (in Persian)
Ashrafpour, A., 2008. Geochemical characteristic, mineralogy and alteration of Arghash gold district, SW Neyshabour, NE Iran. Ph.D. thesis, University of Shahid Beheshti,, Tehran, Iran, 137 pp.
Behroozi, A., 1988. Geological map of Feyzabad , scale 1:100000. Geological Survey of Iran.
Bodnar, R.J., 1993. Revised equation and table for determining the freezing point depression of H2O-NaCl. Geochemica et Cosmochimica Acta, 57(1): 684-685.
Boomeri, M., 1998. Petrography and geochemistry of Sangan Fe-Skarn deposit and its igneous rocks, NE Iran. Ph.D. Thesis, University of Akita, Akita, Japan, 226 pp.
Brown, P.E. and Lamb, W.M., 1989. P-V-T properties of fluids in the system H2O-CO2-NaCl: New graphical presentations and implications for fluid inclusion studies. Geochemica et Cosmochimica Acta, 53(1): 1209-1221.
Dallmeyer, R.D., Brown, M., Grocott, J., Taylor, G.K. and Treloar, P.J., 1996. Mesozoic magmatic and tectonic events within the Andean plate boundary zone, 26O–27O 30'S, north Chile: constraints from 40Ar/39Ar mineral ages. Journal of Geology, 104(1): 19–40.
Eftekharnezhad, J., Aghanabati, A. and Hamzehpour, A., 1974. Geological map of Sabzevar, scale 1:250000.Geological Survey of Iran.
Fuller, R.C., Corvala´n, J., Klohn, C., Klohn, E. and Levi, B., 1965. Geologı´a y yacimientos metalı´feros de Chile. Instituto de Investigaciones Geolo´ gicas, Santiago, 305 pp.
Fuller, R.C. and Ericksen, G.E., 1962. Metallogenic provinces of Chile S.A. Economic Geology, 57(1): 91–106.
Golmohammadi, A., Karimpour, M.H., Malekzadeh Shafaroudi, A. and Mazaheri, S.A., 2014. Petrology and U-Pb zircon dating of intrusive rocksfrom A, C- south, and Dardvay districts, Sangan iron stone mine, Khaf. Journal of economic geology, 2(5): 155-174. (in Persian)
Golmohammadi, A., Mazaheri, S.A., Malekzadeh Shafaroudi, A. and Karimpour, M.H., 2015. U-Pb zircon dating and geochemistry of Sar e Khar and Bermani intrusive bodies, East of Sangan iron stone mine of Khaf. Journal of Petrology, 4(3):1-26. (in Persian)
Grocott, J. and Taylor, G.K., 2002. Magmatic arc fault systems, deformation partitioning and emplacement of granitic complexes in the Coastal Cordillera, northern Chilean Andes (25O30'S to 27O00'S). Journal of Geology Society of London, 159 (1): 425–442.
Gurabjiri, A., 2001. Petrology and Petrogenesis and mineralization of Kuh-e-Zar (Torbat e Heydariyeh). M.Sc. thesis, University of Shahid Beheshti, Tehran, Iran, 126 pp. (in Persian)
Karimpour, M.H., 1991. Source and formation of Sangan iron mine. Proceeding of Iron Stone conference, University of Tehran, Tehran, Iran.
Karimpour, M.H. and Malekzadeh Shafaroudi, A., 2006. Comparison of the geochemistry of source rocks at Tanourjeh Au-bearing magnetite and Sangan Au-free magnetite deposits, Khorasan Razavi, Iran. Iranian Journal of Crystallography and Mineralogy, 13(1): 3–26. (in Persian)
Karimpour, M.H. and Malekzadeh Shafaroudi, A., 2008. Skarn geochemistry – mineralogy and petrology of source rock Sangan Iron mine, Khorasan Razavi, Iran. Scientific Quarterly Journal Geosciences, 65(1): 108–125. (in Persian)
Karimpour, M.H., Malekzadeh Shafaroudi, A., Stern, C.R. and Farmer, L., 2012. Petrogenesis of Granitoids, U–Pb zircon geochronology, Sr–Nd isotopic characteristic, and important occurrence of Tertiary mineralization within the Lut Block, Eastern Iran. Journal of Economic Geology, 4(1): 1–27. (in Persian)
Karimpour, M.H., Saadat, S. and Malekzadeh Shafaroudi, A., 2006. Geochemistry, petrology and mineralization of Tannurjeh porphyry gold–copper. Journal of Sciences of Tehran University, 32(1): 175–189. (in Persian)
Levi, B., NystrÖm, J.O., Thiele, R. and Aberg, G., 1988. Geochemical trends in Mesozoic–Tertiary volcanic rocks from the Andes in central Chile and tectonic implications. Journalof American Earth Sciences 1(1): 63–74.
Malekzadeh Shafaroudi, A., 2004. Petrography, Mineralography and geochemistry of Taknar (Tak I and II) Poly-metal (Cu-Zn-Au-Ag-Pb) and mineralization modeling. M.Sc. Thesis, Ferdowsi University of Mashhad, Mashhad, Iran, 287 pp. (in Persian)
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(5): 256-271.
Marschik, R. and Fontbote´, L., 2001. The Candelaria-Punta del Cobre iron oxide Cu-Au (-Zn-Ag) deposits, Chile. Economic Geology, 96(8): 1799–1826.
Mazlumi Bajestani, A., Hommam, A. and Karimpour, M.H., 2006. Report of Dumortieritemineral from Sarsefidal of Kashmar, Khorasan Razavi Province. 12th symposium of Iranian Crystallography and Mineralogy association, University of Shahid Chamran, Ahwaz, Iran. (in Persian)
Mazlumi Bajestani, A., Karimpour, M.H., Rasa, I., Rahimi, B., Vosoghi Abedini, M., 2009. Kuhe-Zar gold deposit of Torbat-e-Hydarieh: new model of gold mineralization. Iranian Journal of Crystallography and Mineralogy, 16(3): 364–376. (in Persian)
McQuarrie, N., Stock, J.M., Verdel, C. and Wernicke, B.P., 2003. Cenozoic evolution of Neotethys and implications for the causes of plate motions. Geophysical Research Letters, 30(20):1-6. doi:10.1029/ 2003GL017992.
Mpodozis, C. and Ramos, V., 1990. The Andes of Chile and Argentina. Circum-Pacific Council for Energy and Mineral Resources Earth Sciences, 11(1): 59–90.
Muller, R. and Walter, R., 1983. Geology of the Precambrian-Paleozoic Taknar Inlier northwest of Kashmar, Khorasan Province northeast Iran. Geological Survey of Iran, Tehran, Report 50, 252 pp.
Naderi Mighan, N. and Torshizian, H., 1999. Geological map of Kadkan , scale 1:100000. Geological Survey of Iran.
Ray, G.E. and Dick, L.A., 2002. The Productora prospect in north-central Chile: An example of an intrusion-related Candelaria type Fe-Cu-Au hydrothermal system. In: T.M. Porter, (Editor),Hydrothermal iron oxide copper-gold and related deposits: A global perspective 2. PGS Publishing, Linden Park, pp. 131–151.
Rossetti, F., Nasrabady, M., Theye, T., Gerdes, A., Monie, P., Lucci, F. and Vignaroli, G., 2014. Adakite differentiation and emplacement in a subduction channel: The late Paleocene Sabzevarmagmatism (NE Iran). Geological Society of America Bulletin, 126(1):317–343.
Sahandi, M.R. and Hoseini, M., 1990. Geological map of Sabzevar, scale 1:100000. Geological Survey of Iran.
Schmid, R., Fettes, D., Harte, B., Davis, E. and Desmons, J., 2007. A systematic nomenclature for metamorphic rocks. 1. How to name a metamorphic rock. Recommendations by the IUGS Subcommission on the systematics of metamorphic rocks.SCMR website (www.bgs.ac.uk/SCMR).
Shafaii Moghadam, H.S., Corfu, F., Chiaradia, M., Stern, R.J. and Ghorbani, G., 2014. Sabzevar Ophiolite, NE Iran: Progress from embryonic oceanic lithosphere into magmatic arc constrained by new isotopic and geochemical data. Lithos, 210–211(1): 224–241.
Shafaii Moghadam, H.S., Li, X.H., Ling, X.X., Santos, J.F. and Stern, R.J., 2015. Eocene Kashmar granitoids (NE Iran): Petrogenetic constraints from U–Pb zircon geochronology and isotope geochemistry. Lithos, 216–217(1): 118–135.
Sheppherd, T.J., Rankin, A.H. and Alderton, D.H.M., 1985. A Practical Guide to Fluid Inclusion Studies. Blackie and Son, Glasgow, 239 pp.
Sillitoe, R.H., 2003. Iron oxide-copper-gold deposits: An Andean view. Mineralium Deposita, 38(7): 787–812.
Vaezipour, M.J., Alavi Tehrani, M.J. and Behroozi, A., 1993. Geological map of Torbat e Heydariyeh, scale 1:250000. Geological Survey of Iran.
Walker, R., Jackson, J. and Baker, C., 2004. Active faulting and seismicity of the Dasht-e-Bayaz region, eastern Iran. Geophysic Journal, 157(1): 265 – 282.
Yusofi, L., Karimpour, M.H. and Heydarian Shahri, M.R., 2009. Geology, mineralogy, fluid inclusion microthermometry, and ground magnetic survey of magnetitespcularite–copper–gold mineralization of Shaharak prospect area, Torbat-e-Hydarieh, Iran. Iranian Journal of Crystallography and Mineralogy, 16(1): 505–516. (in Persian)
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  • Receive Date: 21 February 2016
  • Accept Date: 29 May 2016

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