Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-10T10:41:18.574Z Has data issue: false hasContentIssue false
  • English
  • Français

Zircon U–Pb ages, geochemistry and Sr–Nd isotopes of the Golshekanan granitoid, Urumieh–Dokhtar magmatic arc, Iran: evidence for partial melting of juvenile crust

Published online by Cambridge University Press:  15 December 2020

Fatemeh Sarjoughian Open the ORCID record for Fatemeh Sarjoughian [Opens in a new window] ,
Bahareh Zahedi ,
Hossein Azizi ,
Wenli Ling ,
David R. Lentz  and
Yoshihiro Asahara
Fatemeh Sarjoughian*
Affiliation:
Department of Earth Sciences, Faculty of Sciences, University of Kurdistan, Sanandaj, Iran
Bahareh Zahedi
Affiliation:
Department of Earth Sciences, Faculty of Sciences, University of Kurdistan, Sanandaj, Iran
Hossein Azizi
Affiliation:
Department of Mining engineering, Faculty of Engineering, University of Kurdistan, Sanandaj, Iran
Wenli Ling
Affiliation:
Faculty of Earth Sciences, China University of Geosciences, Wuhan430074, China
David R. Lentz
Affiliation:
Department of Earth Sciences, University of New Brunswick, Fredericton, NBE3B 5A3, Canada
Yoshihiro Asahara
Affiliation:
Department of Earth and Environmental Sciences, Graduate School of Environmental Studies, Nagoya University, Nagoya, Japan
*
Author for correspondence: Fatemeh Sarjoughian, Email: Fsarjoughian2@gmail.com
Get access Rights & Permissions [Opens in a new window]

Abstract

The Golshekanan granitoid body is situated in the central part of the Urumieh–Dokhtar magmatic arc (UDMA) in central Iran, and includes granite and granodiorite with minor monzonite and diorite. Zircon U–Pb dating yields a late Eocene (Priabonian) crystallization age of 37.6 ± 0.2 Ma. The body is calc-alkaline and metaluminous to weakly peraluminous (A/CNK ≤ 1.10) with SiO2 ranging from 61.1 to 71.5 wt% and MgO from 0.8 to 3.3 wt%, with Na2O + K2O of 4.0–8.5 wt%. Primitive mantle-normalized trace-element patterns display enrichments in the large-ion lithophile elements (LILE), such as Rb, Cs, Ba and K, and depletion from the high-field-strength elements (HFSEs), such as Nb, Ti, Ta and P. The rocks are enriched in LREEs relative to HREEs (average (La/Yb)CN = 4.3) and exhibit weak negative Eu anomalies (average Eu/Eu* = 0.75), revealing typical active continental margin arc affinity. The low initial 87Sr/86Sr ratios (0.70440–0.70504) and notable positive ϵNd(t) values (+4.0 to +5.2) indicate an origin by partial melting of juvenile rocks in the lower crust, possibly with some involvement of sub-continental lithospheric mantle beneath Central Iran. These processes probably occurred due to the Neo-Tethys oceanic slab retreat and (or) rollback during late Eocene time.

Keywords

active continental margingranitoidSr–Nd isotope ratiosjuvenile crustNeo-Tethys subductionUrumieh–Dokhtar magmatic arcIran
Type
Original Article
Information
Geological Magazine , Volume 158 , Issue 7 , July 2021 , pp. 1289 - 1304
Copyright
© The Author(s), 2020. Published by Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Agard, P, Omrani, J, Jolivet, L and Mouthereau, F (2005) Convergence history across Zagros (Iran): constraints from collisional and earlier deformation. International Journal of Earth Sciences 94, 401–19.CrossRefGoogle Scholar
Agard, P, Omrani, J, Jolivet, L, Whitechurch, H, Vrielynck, B, Spakman, W, Monié, P, Meyer, B and Wortel, R (2011) Zagros orogeny: a subduction-dominated process. Geological Magazine 148, 692725.CrossRefGoogle Scholar
Ahmad, T and Posht Kuhi, M (1993) Geochemistry and Petrogenesis of Urumiah–Dokhtar Volcanics Around Nain and Rafsanjan Areas: A Preliminary Study., Iranian. Tehran: Ministry of Mines and Metals, Treatise on the Geology of Iran, 90 p.Google Scholar
Ahmadian, J, Sarjoughian, F, Lentz, D, Esna-Ashari, A, Murata, M and Ozawa, H (2016) Eocene K-rich adakitic rocks in the Central Iran: implications for evaluating its Cu–Au–Mo metallogenic potential. Ore Geology Reviews 72, 323–42.CrossRefGoogle Scholar
Ahmadzadeh, G, Jahangiri, A, Lentz, D and Mojtahedi, M (2010) Petrogenesis of Plio-Quaternary post-collisional ultrapotassic volcanism in NW of Marand, NW Iran. Journal of Asian Earth Sciences 39, 3750.CrossRefGoogle Scholar
Alavi, M (1994) Tectonics of the Zagros orogenic belt of Iran: new data and interpretations. Tectonophysics 229, 211–38.CrossRefGoogle Scholar
Alirezaei, S and Hassanzadeh, J (2012) Geochemistry and zircon geochronology of the Permian A type Hasanrobat granite, Sanandaj-Sirjan belt: a new record of the Gondwana break-up in Iran. Lithos 151, 122–34.CrossRefGoogle Scholar
Ao, S, Xiao, W, Khalatbari Jafari, M, Talebian, M, Chen, L, Wan, B, Ji, W and Zhang, Z (2016) U–Pb zircon ages, field geology and geochemistry of the Kermanshah ophiolite (Iran): From continental rifting at 79 Ma to oceanic core complex at ca. 36 Ma in the southern Neo-Tethys. Gondwana Research 31, 305–18.CrossRefGoogle Scholar
Asadi, S (2018) Triggers for the generation of post-collisional porphyry Cu systems in the Kerman magmatic copper belt, Iran: New constraints from elemental and isotopic (Sr–Nd–Hf–O) data. Gondwana Research 64, 97121.CrossRefGoogle Scholar
Azizi, H and Asahara, Y (2013) Juvenile granite in the Sanandaj–Sirjan Zone, NW Iran: late Jurassic–early Cretaceous arc–continent collision. International Geology Review 55, 1523–40.CrossRefGoogle Scholar
Babazadeh, S, Ghorbani, MR, Bröcker, M, D’Antonio, M, Cottle, J, Gebbing, T, Mazzeo, FC and Ahmadi, P (2017) Late Oligocene–Miocene mantle upwelling and interaction inferred from mantle signatures in gabbroic to granitic rocks from the Urumieh–Dokhtar arc, south Ardestan, Iran. International Geology Review 59, 1590–608.CrossRefGoogle Scholar
Babazadeh, S, Ghorbani, MR, Cottle, JM and Bröcker, M (2019) Multistage tectono-magmatic evolution of the central Urumieh–Dokhtar magmatic arc, south Ardestan, Iran: Insights from zircon geochronology and geochemistry. Geological Journal 54, 2447–71.CrossRefGoogle Scholar
Bahroudi, A (1999) Geological Map of Shahrab. Scale 1:100 000. Tehran: Geological Survey of Iran.Google Scholar
Ballato, P, Uba, CE, Landgraf, A, Strecker, MR, Sudo, M, Stockli, DF, Friedrich, A and Tabatabaei, SH (2011) Arabia-Eurasia continental collision: Insights from late Tertiary foreland-basin evolution in the Alborz Mountains, northern Iran. Geological Society of America Bulletin 123, 106–31.CrossRefGoogle Scholar
Beard, JS and Lofgren, GE (1991) Dehydration melting and water-saturated melting of basaltic and andesitic greenstones and amphibolites at 1, 3, and 6.9 kb. Journal of Petrology 32, 365401.CrossRefGoogle Scholar
Belousova, E, Griffin, WL, O’Reilly, SY and Fisher, NL (2002) Igneous zircon: trace element composition as an indicator of source rock type. Contributions to Mineralogy and Petrology 143, 602–22.CrossRefGoogle Scholar
Berberian, F and Berberian, M (1981) Tectono-plutonic episodes in Iran. In Zagros-Hindu Kush-Himalaya Geodynamic Evolution (eds Gupta, HK and Delany, FM), pp. 532. Washington, DC: American Geophysical Union.CrossRefGoogle Scholar
Chappell, BW and White, AJ (1974) Two contrasting granite types. Pacific Geology 8, 173–74.Google Scholar
Chekani Moghadam, M, Tahmasbi, Z, Ahmadi-Khalaji, A and Santos, JF (2018) Petrogenesis of Rabor-Lalehzar magmatic rocks (SE Iran): Constraints from whole rock chemistry and Sr-Nd isotopes. Chemie der Erde 78, 5877.CrossRefGoogle Scholar
Chiu, HY, Chung, SL, Zarrinkoub, MH, Mohammadi, SS, Khatib, MM and Iizuka, Y (2013) Zircon U–Pb age constraints from Iran on the magmatic evolution related to Neotethyan subduction and Zagros orogeny. Lithos 162, 7087.CrossRefGoogle Scholar
Chiu, HY, Chung, SL, Zarrinkoub, MH, Melkonyan, R, Pang, KN, Lee, HY, Wang, KL, Mohammadi, SS and Khatib, MM (2017) Zircon Hf isotopic constraints on magmatic and tectonic evolution in Iran: Implications for crustal growth in the Tethyan orogenic belt. Journal of Asian Earth Sciences 145, 652–69.CrossRefGoogle Scholar
Clemens, JD and Stevens, G (2012) What controls chemical variation in granitic magmas? Lithos 134–135, 317–29.CrossRefGoogle Scholar
Clemens, JD, Stevens, G and Farina, F (2011) The enigmatic sources of I-type granites: the peritectic connexion. Lithos 126, 174181.CrossRefGoogle Scholar
Daneshvar, N, Maanijou, M, Azizi, H and Asahara, Y (2019) Petrogenesis and geodynamic implications of an Ediacaran (550 Ma) granite complex (metagranites), southwestern Saqqez, northwest Iran. Journal of Geodynamics 132, 101669.CrossRefGoogle Scholar
Davoudzadeh, M (1972) Geology and Petrology of the area North of Nain, Central Iran. Tehran: Geological Survey of Iran, 89 p.Google Scholar
Deng, C, Wan, B, Dong, L, Talebian, M, Windley, BF, Dadashzadeh, H, Mohammadi, B and Barati, B (2018) Miocene porphyry copper deposits in the Eastern Tethyan orogenic belt: Using Sr, O isotopes and Sr/Y ratios to predict the source of ore-related and ore-barren magmas. Gondwana Research 62, 1426.CrossRefGoogle Scholar
Douce, P (1999) Amphibolite to granulite transition in aluminous greywackes from the Sierra de Comechingones, Córdoba, Argentina. Journal of Metamorphic Geology 17, 415–34.Google Scholar
Gromet, P and Silver, LT (1987) REE variations across the Peninsular Ranges batholith: Implications for batholithic petrogenesis and crustal growth in magmatic arcs. Journal of Petrology 28, 75125.CrossRefGoogle Scholar
Guo, F, Fan, W, Li, C, Gao, X and Miao, L (2009) Early Cretaceous highly positive ϵNd felsic volcanic rocks from the Hinggan Mountains, NE China: origin and implications for Phanerozoic crustal growth. International Journal of Earth Sciences 98, 1395–411.CrossRefGoogle Scholar
Gürsu, S (2016) A new petrogenetic model for meta-granitic rocks in the central and southern Menderes Massif–W Turkey: Implications for Cadomian crustal evolution within the Pan-African mega-cycle. Precambrian Research 275, 450–70.CrossRefGoogle Scholar
Hacker, BR, Kelemen, PB and Behn, MD (2015) Continental lower crust. Annual Review of Earth and Planetary Sciences 43, 167205.CrossRefGoogle Scholar
Haschke, M, Ahmadian, J, Murata, M and McDonald, I (2010) Copper mineralization prevented by arc-root delamination during Alpine-Himalayan collision in central Iran. Economic Geology 105, 855–65.CrossRefGoogle Scholar
Hassanzadeh, J, Stockli, DF, Horton, BK, Axen, GJ, Stockli, LD, Grove, M, Schmitt, AK and Walker, JD (2008) U–Pb zircon geochronology of late Neoproterozoic–Early Cambrian granitoids in Iran: implications for paleogeography, magmatism, and exhumation history of Iranian basement. Tectonophysics 451, 7196.CrossRefGoogle Scholar
Honarmand, M, Rashidnejad Omran, N, Neubauer, F, Hashem Emami, M, Nabatian, G, Liu, X, Dong, Y, Quadt, A and Chen, B (2014) Laser-ICP-MS U–Pb zircon ages and geochemical and Sr–Nd–Pb isotopic compositions of the Niyasar plutonic complex, Iran: constraints on petrogenesis and tectonic evolution. International Geology Review 56, 104–32.CrossRefGoogle Scholar
Horton, BK, Hassanzadeh, J, Stockli, DF, Axen, GJ, Gillis, RJ, Guest, B, Amini, A, Fakllari, MD, Zamanzadeh, SM and Grove, M (2008) Detrital zircon provenance of Neoproterozoic to Cenozoic deposits in Iran: Implications for chronostratigraphy and collisional tectonics. Tectonophysics 451, 97122.CrossRefGoogle Scholar
Jahn, BM, Wu, F and Chen, B (2000a) Massive granitoid generation in Central Asia: Nd isotope evidence and implication for continental growth in the Phanerozoic. Episodes 23, 8292.CrossRefGoogle Scholar
Jahn, BM, Wu, F and Hong, D (2000b) Important crustal growth in the Phanerozoic: Isotopic evidence of granitoids from east-central Asia. Journal of Earth System Science 109, 520.CrossRefGoogle Scholar
Jahn, BM, Valui, G, Kruk, N, Gonevchuk, V, Usuki, M and Wu, JT (2015) Emplacement ages, geochemical and Sr–Nd–Hf isotopic characterization of Mesozoic to early Cenozoic granitoids of the Sikhote-Alin Orogenic Belt, Russian Far East: Crustal growth and regional tectonic evolutionJournal of Asian Earth Sciences 111, 872918.CrossRefGoogle Scholar
Jiang, ZQ, Wang, Q, Wyman, DA, Li, ZX, Yang, JH, Shi, XB, Ma, L, Tang, GJ, Gou, GN, Jia, XH and Guo, HF (2014) Transition from oceanic to continental lithosphere subduction in southern Tibet: Evidence from the Late Cretaceous–Early Oligocene (~ 91–30 Ma) intrusive rocks in the Chanang–Zedong area, southern Gangdese. Lithos 196, 213–31.CrossRefGoogle Scholar
Kazemi, K, Kananian, A, Xiao, Y and Sarjoughian, F (2019) Petrogenesis of Middle-Eocene granitoids and their mafic microgranular enclaves in central Urmia-Dokhtar Magmatic Arc (Iran): Evidence for interaction between felsic and mafic magmas. Geoscience Frontiers 10, 705–23.CrossRefGoogle Scholar
Kazemi, K, Kananian, A, Yilin, X and Sarjoughian, F (2020) Role of magma mixing in generating of the Gheshlagh-Aftabrow intrusions, SW Buin-Zahra, Iran: Evidence for a juvenile origin from geochemical and Sr-Nd isotopic data. Geological Journal 55, 253–79.CrossRefGoogle Scholar
Kirkland, C L, Smithies, R H, Taylor, R J M, Evans, N and McDonald, B (2015) Zircon Th/U ratios in magmatic environs. Lithos 212, 397414.CrossRefGoogle Scholar
Kretz, R (1983) Symbols for rock-forming minerals. American Mineralogist 68, 277–79.Google Scholar
Kröner, A, Kovach, V, Belousova, E, Hegner, E, Armstrong, R, Dolgopolova, A, Seltmann, R, Alexeiev, DV, Hoffmann, JE, Wong, J and Sun, M (2014) Reassessment of continental growth during the accretionary history of the Central Asian Orogenic Belt. Gondwana Research 25, 103–25.CrossRefGoogle Scholar
Li, JX, Qin, KZ, Li, GM, Cao, MJ, Xiao, B, Chen, L, Zhao, JX, Evans, NJ and McInnes, BIA (2012) Petrogenesis and thermal history of the Yulong porphyry copper deposit, Eastern Tibet: insights from U-Pb and U-Th/He dating, and zircon Hf isotope and trace element analysis. Mineralogy and Petrology 105, 201–21.CrossRefGoogle Scholar
Liu, Y, Hu, Z, Gao, S, Günther, D, Xu, J, Gao, C and Chen, H (2008) In situ analysis of major and trace elements of anhydrous minerals by LA-ICP-MS without applying an internal standard. Chemical Geology 257, 3443.CrossRefGoogle Scholar
López, S and Castro, A (2001) Determination of the fluid absent solidus and supersolidus phase relationships of MORB-derived amphibolites in the range 4-14 kbar. American Mineralogist 86, 1396–403.CrossRefGoogle Scholar
Ludwig, KR (2008) A Geochronological Toolkit for Microsoft Excel. Berkeley: Berkeley Geochronology Center, Special Publication.Google Scholar
Mansouri Esfahani, M, Khalili, M and Bakhshi, M (2017) Petrogenesis of Soheyle-Pakuh and Golshekanan granitoid based on mineral chemistry of ferromagnesian minerals (north of Nain), Iran. Journal of African Earth Sciences 129, 973–86.CrossRefGoogle Scholar
Martin, H (1987) Petrogenesis of Archaean trondhjemites, tonalites, and granodiorites from eastern Finland: major and trace element geochemistry. Journal of Petrology 28, 921–53.CrossRefGoogle Scholar
Middlemost, EA (1994) Naming materials in the magma/igneous rock system. Earth-Science Reviews 37, 215–24.CrossRefGoogle Scholar
Mo, X, Hou, Z, Niu, Y, Dong, G, Qu, X, Zhao, Z and Yang, Z (2007) Mantle contributions to crustal thickening during continental collision: evidence from Cenozoic igneous rocks in southern Tibet. Lithos 96, 225–42.CrossRefGoogle Scholar
Mohajjel, M, Fergusson, CL and Sahandi, MR (2003) Cretaceous–Tertiary convergence and continental collision, Sanandaj–Sirjan zone, western Iran. Journal of Asian Earth Sciences 21, 397412.CrossRefGoogle Scholar
Nazarinia, A, Mortazavia, M, Arvinb, M, Hu, R, Zhao, C and Poosti, M (2020) U-Pb zircon dating, Sr-Nd isotope and petrogenesis of Sarduiyeh granitoid in SE of the UDMB, Iran: implication for the source origin and magmatic evolution. International Geology Review 62(13–14), 1796–814, doi: 10.1080/00206814.2018.1514668.CrossRefGoogle Scholar
Nouri, F, Azizi, H, Stern, R J, Asahara, Y, Khodaparast, S, Madanipour, S and Yamamoto, K (2018) Zircon U-Pb dating, geochemistry and evolution of the Late Eocene Saveh magmatic complex, central Iran: Partial melts of sub-continental lithospheric mantle and magmatic differentiation. Lithos 314–315, 274–92.CrossRefGoogle Scholar
Patiño Douce, AEP (1999) What do experiments tell us about the relative contributions of crust and mantle to the origin of granitic magmas? In Understanding Granites: Integratng New and Classical Techniques (eds Castro, A, Fernandez, C and Vigneresse, JL), pp. 5575. Geological Society of London, Special Publication no. 168.Google Scholar
Pearce, J (1996) Sources and settings of granitic rocks. Episodes 19, 120–25.CrossRefGoogle Scholar
Peng, T, Zhao, G, Fan, W, Peng, B and Mao, Y (2014) Zircon geochronology and Hf isotopes of Mesozoic intrusive rocks from the Yidun terrane, Eastern Tibetan Plateau: petrogenesis and their bearings with Cu mineralization. Journal of Asian Earth Sciences 80, 1833.CrossRefGoogle Scholar
Rapp, RP and Watson, EB (1995) Dehydration melting of metabasalt at 8–32 kbar: implications for continental growth and crust-mantle recycling. Journal of Petrology 36, 891931.CrossRefGoogle Scholar
Ramezani, J and Tucker, RD (2003) The Saghand region, Central Iran: U-Pb geochronology, petrogenesis and implications for Gondwana tectonics. American Journal of Science 303, 622–65.CrossRefGoogle Scholar
Rezaei-Kahkhaei, M, Galindo, C, Pankhurst, RJ and Esmaeily, D (2011) Magmatic differentiation in the calc-alkaline Khalkhab–Neshveh pluton, Central Iran. Journal of Asian Earth Sciences 42, 499514.CrossRefGoogle Scholar
Roberts, MP and Clemens, JD (1993) Origin of high-potassium, calc-alkaline, I-type granitoids. Geology 21, 825–28.2.3.CO;2>CrossRefGoogle Scholar
Ross, PS and Bédard, JH (2009) Magmatic affinity of modern and ancient subalkaline volcanic rocks determined from trace-element discriminant diagrams. Canadian Journal of Earth Sciences 46, 823–39.CrossRefGoogle Scholar
Rossetti, F, Nozaem, R, Lucci, F, Vignaroli, G, Gerdes, A, Nasrabadi, M and Theye, T (2015) Tectonic setting and geochronology of the Cadomian (Ediacaran- Cambrian) magmatism in central Iran, Kuh-e-Sarhangi region (NW Lut Block). Journal of Asian Earth Sciences 102, 2444.CrossRefGoogle Scholar
Rudnick, RL and Fountain, DM (1995) Nature and composition of the continental crust: a lower crustal perspective. Reviews of Geophysics 33, 267309.CrossRefGoogle Scholar
Rushmer, T (1991) Partial melting of two amphibolites: contrasting experimental results under fluid-absent conditions. Contributions to Mineralogy and Petrology 107, 4159.CrossRefGoogle Scholar
Sarjoughian, F, Azizi, M, Lentz, DR and Ling, W (2019) Geochemical and isotopic evidence for magma mixing/mingling in the Marshenan intrusion: Implications for juvenile crust in the Urumieh–Dokhtar Magmatic Arc, Central Iran. Geological Journal 54, 2241–60.CrossRefGoogle Scholar
Sarjoughian, F, Javadi, S, Azizi, H, Ling, W, Asahara, Y and Lentz, D (2020) Geochemical and Sr–Nd isotopic constraints on the genesis of the Soheyle-PaKuh granitoid rocks (central Urumieh-Dokhtar magmatic belt, Iran). International Geology Review 62(13–14), 1769–95, doi: 10.1080/00206814.2019.1579676.CrossRefGoogle Scholar
Sarjoughian, F and Kananian, A (2017) Zircon U-Pb geochronology and emplacement history of intrusive rocks in the Ardestan section, central Iran. Geologica Acta 15, 2536.Google Scholar
Sarjoughian, F, Kananian, A, Haschke, M and Ahmadian, J (2012) Geochemical signature of Eocene Kuh-e Dom shoshonitic dikes in NE Ardestan, Central Iran: implications for melt evolution and tectonic setting. Journal of Geosciences 57, 241–64.Google Scholar
Sarjoughian, F, Lentz, D, Kananian, A, Ao, S and Xiao, W (2018) Geochemical and isotopic constraints on the role of juvenile crust and magma mixing in the UDMB magmatism, Iran: evidence from mafic microgranular enclaves and cogenetic granitoids in the Zafarghand igneous complex. International Journal of Earth Sciences 107, 1127–51.CrossRefGoogle Scholar
Şengör, AMC (1987) Cross-faults and differential stretching of hanging walls in regions of low angle normal faulting: examples from western Turkey. In Continental Extensional Tectonics (eds Coward, MP, Dewey, JF and Hancock, PL), pp. 575–89. Geological Society of London, Special Publication no. 28.Google Scholar
Sepidbar, F, Ao, S, Palin, RM, Li, QL and Zhang, Z (2019) Origin, age and petrogenesis of barren (low-grade) granitoids from the Bezenjan-Bardsir magmatic complex, southeast of the Urumieh-Dokhtar magmatic belt, Iran. Ore Geology Reviews 104, 132–47.CrossRefGoogle Scholar
Sepidbar, F, Mirnejad, H, Ma, C and Moghadam, HS (2018) Identification of Eocene-Oligocene magmatic pulses associated with flare-up in east Iran: Timing and sources. Gondwana Research 57, 141–56.CrossRefGoogle Scholar
Shabanian, N, Davoudian, A R, Dong, Y and Liu, X (2018) U-Pb zircon dating, geochemistry and Sr-Nd-Pb isotopic ratios from Azna-Dorud Cadomian metagranites, Sanandaj-Sirjan zone of western Iran. Precambrian Research 306, 4160.CrossRefGoogle Scholar
Shafaii Moghadam, H, Corfu, F, Chiaradia, M, Stern, RJ 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, 224–41.CrossRefGoogle Scholar
Shen, P, Pan, H, Cao, C, Zhong, S and Li, C (2017) The formation of the Suyunhe large porphyry Mo deposit in the West Junggar terrain, NW China: Zircon U–Pb age, geochemistry and Sr–Nd–Hf isotopic results. Ore Geology Reviews 81, 808–28.CrossRefGoogle Scholar
Shomali, ZH, Keshvari, F, Hassanzadeh, J and Mirzaei, N (2011) Lithospheric structure beneath the Zagros collision zone resolved by non-linear teleseismic tomography. Geophysical Journal International 187, 394406.CrossRefGoogle Scholar
Simonetti, A, Heaman, LM, Chacko, T and Banerjee, NR (2006) In situ petrographic thin section U–Pb dating of zircon, monazite, and titanite using laser ablation–MC–ICP-MS. International Journal of Mass Spectrometry 253, 8797.CrossRefGoogle Scholar
Soesoo, A (2000) Fractional crystallization of mantle-derived melts as a mechanism for some I-type granite petrogenesis: an example from Lachlan Fold Belt, Australia. Journal of the Geological Society 157, 135–49.CrossRefGoogle Scholar
Stöcklin, J (1968) Structural history and tectonics of Iran: a review. AAPG Bulletin 52, 1229–58.Google Scholar
Sun, SS and McDonough, WS (1989) Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes. In Magmatism in the Ocean Basins (eds Saunders, AD and Norry, MJ), pp. 313–45. Geological Society of London, Special Publication no. 42.Google Scholar
Tanaka, T, Togashi, S, Kamioka, H, Amakawa, H, Kagami, H, Hamamoto, T, Yuhara, M, Orihashi, Y, Yoneda, S, Shimizu, H, Kunimaru, T, Takahashi, K, Yanagi, T, Nakano, T, Fujimaki, H, Shinjo, R, Asahara, Y, Tanimizu, M and Dragusanu, C (2000) JNdi-1: a neodymium isotopic reference in consistency with LaJolla neodymium. Chemical Geology 168, 279–81.CrossRefGoogle Scholar
Tang, G J, Wang, Q, Wyman, D A, Chung, S L, Chen, H Y and Zhao, ZH (2017) Genesis of pristine adakitic magmas by lower crustal melting: A perspective from amphibole composition. Journal of Geophysical Research: Solid Earth 122, 1934–48.Google Scholar
Taylor, SR and McLennan, SM (1985) The Continental Crust: Its Composition and Evolution. Oxford: Blackwell, 312 p.Google Scholar
van Middelaar, WT and Keith, JD (1990) Mica chemistry as an indicator of halogen and oxygen fugacities in the CanTung and other W-related granitoids in the North American Cordillera. In Ore-Bearing Granite Systems: Petrogenesis and Mineralizing Processes (eds Stein, HJ and Hannah, JL), pp. 205–20. Geological Society of America, Special Paper no. 246.CrossRefGoogle Scholar
Verdel, C, Wernicke, BP, Hassanzadeh, J & Guest, B (2011) A Paleogene extensional arc flare-up in Iran. Tectonics 30(3), 0000, doi: 10.1029/2010TC002809.CrossRefGoogle Scholar
Wan, B, Deng, C, Najafi, A, Hezareh, MR, Talebian, M, Dong, L, Chen, L and Xiao, W (2018) Fertilizing porphyry Cu deposits through deep crustal hot zone melting. Gondwana Research 60, 179–85.CrossRefGoogle Scholar
Wilson, BM (1989) Igneous Petrogenesis: A Global Tectonic Approach. London: Unwin Hyman, London, 456 p.CrossRefGoogle Scholar
Wu, FY, Jahn, BM, Wilde, S and Sun, DY (2000) Phanerozoic crustal growth: U–Pb and Sr–Nd isotopic evidence from the granites in northeastern China. Tectonophysics 328, 89113.CrossRefGoogle Scholar
Wyllie, PJ and Wolf, MB (1993) Amphibolite dehydration-melting: sorting out the solidus. In Magmatic Processes and Plate Tectonics (eds Prichard, HM, Alabaster, T, Harris, NBW and Neary, CR), pp. 405–16. Geological Society of London, Special Publication no. 76.Google Scholar
Xiao, L, Zhang, HF, Clemens, JD, Wang, QW, Kan, ZZ, Wang, KM, Ni, PZ and Liu, XM (2007) Late Triassic granitoids of the eastern margin of the Tibetan Plateau: geochronology, petrogenesis and implications for tectonic evolution. Lithos 96, 436–52.CrossRefGoogle Scholar
Zhang, D, Wei, J, Fu, L, Chen, H, Tan, J, Li, Y, Shi, W and Tian, N (2015) Formation of the Jurassic Changboshan-Xieniqishan highly fractionated I-type granites, northeastern China: implication for the partial melting of juvenile crust induced by asthenospheric mantle upwellingGeological Journal 50, 122–38.CrossRefGoogle Scholar
Zhang, W, Chen, H, Han, J, Zhao, L, Huang, J, Yang, J and Yan, X (2016) Geochronology and geochemistry of igneous rocks in the Bailingshan area: Implications for the tectonic setting of late Paleozoic magmatism and iron skarn mineralization in the eastern Tianshan, NW China. Gondwana Research 38, 4059.CrossRefGoogle Scholar
Zhao, SQ, Tan, J, Wei, JH, Tian, N, Zhang, DH, Liang, SN and Chen, JJ (2015) Late Triassic Batang Group arc volcanic rocks in the northeastern margin of Qiangtang terrane, northern Tibet: partial melting of juvenile crust and implications for Paleo-Tethys ocean subduction. International Journal of Earth Sciences 104, 369–87.CrossRefGoogle Scholar
Zhu, DC, Pan, GT, Chung, SL, Liao, ZL, Wang, LQ and Li, GM (2008) SHRIMP zircon age and geochemical constraints on the origin of Lower Jurassic volcanic rocks from the Yeba Formation, southern Gangdese, South Tibet. International Geology Review 50, 442–71.CrossRefGoogle Scholar