[1] Berberian M., King G.C.P., "Towards a paleogeography and tectonic evolution of Iran", Canadian Journal of Earth Sciences 18 (1981) 210-265.
[2] Shahabpour J., "Island-arc affinity of the Central Iranian volcanic belt", Journal of Asian Earth Sciences 30 (2007) 652-665.
[3] Omrani J., Agard P., Whitechurch H., Benoit M., Prouteau G., Jolivet L., "Arc-magmatism and subduction history beneath the Zagros Mountains, Iran: a new report of adakites and geodynamic consequences", Lithos 106 (2008) 380-398.
[4] Jafari A., Ghasemi H., "Geologic history of The Sabzevar oceanic Basin, NE Iran; An overview from continental rifting to obduction in the Neo Tethys oceanic system", Journal of Asian Earth science 245 (2023) 10559.
[5] Jafari A., Ao S., Jamei S., Ghasemi H., "Evolution of the Zagros sector of Neo-Tethys: Tectonic and magmatic events that shaped its rifting, seafloor spreading and subduction history", Earth-Science Reviews 241 (2023) 104419.
[6] Alavi M., "Regional stratigraphy of the Zagros fold-thrust belt of Iran and its proforeland evolution", American Journal of Science 304 (2004) 1-20.
[7] Alavi M., "Tectonics of the Zagros orogenic belt of Iran: new data and interpretations", Tectonophysics 229 (1994) 211-238.
[8] Hosseini S.Z., Arvin M., Oberhansli R., Dargahi S., "Geochemistry and tectonic setting of pleistocene basaltic lava flows in the shahre-babak area, NW of Kerman Iran: Implication for the Evolution of Urumieh Dokhtar Magmatic Assemblage", Journal of Sciences, Islamic Republic of Iran 20 (2009) 331-342.
[9] Verdel C., Wernicke B.P., Hassanzadeh J., Guest B., "A Paleogene extensional arc flare-up in Iran", Tectonics 30 (2011) 0-0.
[10] Agard P., Omrani J., Jolivet L., Whitechurch H., Vrielynck B., Spakman W., Monié P., Meyer B., Wortel R., "Zagros orogeny: a subduction-dominated process", Geological Magazine 148 (2011) 692-725.
[11] Rezeau H., Moritz R., Wotzlaw J.F., Tayan R., Melkonyan R., Ulianov A., Selby D., d’Abzac F.X., Stern R.A., "Temporal and genetic link between incremental pluton assembly and pulsed porphyry Cu-Mo formation in accretionary orogens", Geology 44 (2016) 627-630.
[12] Chiu H.Y., Chung S.L., Zarrinkoub M.H., Mohammadi S.S., Khatib M.M., Iizuka Y., "Zircon U–Pb age constraints from Iran on the magmatic evolution related to Neotethyan subduction and Zagros orogeny", Lithos 162 (2013) 70-87.
[13] Chiu H.Y., Chung S.L., Zarrinkoub M.H., Melkonyan R., Pang K.N., Lee H.Y., Wang K.L., Mohammadi S.S., Khatib M.M, "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 (2017) 652-669.
[14] Raeisi D., Zhao M., Babazadeh S., Long L.E., Hajsadeghi S., Modabberi S., "Synthesis on productive, sub-productive and barren intrusions in the Urumieh-Dokhtar magmatic arc, Iran, constraints on geochronology and geochemistry", Ore Geology Reviews 132 (2021) 103997.
[15] Babazadeh S., Raeisi D., D'Antonio M., Zhao M., Long L.E., Cottle J.M., Modabberi S., "Petrogenesis of Miocene igneous rocks in the Tafresh area (central Urumieh‐Dokhtar magmatic arc, Iran): Insights into mantle sources and geodynamic processes", Geological Journal 57 (2022) 2884-2903.
[16] Babazadeh S., Furman T., Santosh M., Raeisi D., Choi S.H., D'Antonio M., "Middle to Late Miocene K-rich magmatism in Central Iran: Geochemical characterization of the post-collision mantle beneath the Urumieh–Dokhtar magmatic arc", Chemical Geology 665 (2024) 122308.
[17] Berberian F., Berberian M., "Tectono–Plutonic Episodes in Iran", Geological Survey of Iran, Report 52 (1981) 566-593.
[18] Berberian F., Muir I.D., Pankhurst R.J., Berberian M., "Late Cretaceous and early Miocene Andean type plutonic activity in northern Makran and central Iran", Journal of Geological Society of London 139 (1982) 605-614.
[19] Ghorbani M., "The geology of Iran: tectonic, magmatism and metamorphism", Springer Nature (2021).
[20] Rasouli J., Ghorbani M., Ahadnejad V., Poli G., "Calk-alkaline magmatism of Jebal-e-Barez plutonic complex, SE Iran: implication for subduction-related magmatic arc", Arabian Journal of Geosciences 9 (2016) 1-22.
[21] Behpour S., Moradian A., Ahmadipour H., Nakashima K., "Mineralogy, petrology and geochemistry of mafic dikes in the southeast Jebal-E-Barez Granitoids (Bam, Kerman province, Iran): Studies from mafic dikes formed in a volcanic arc-setting", Turkish Journal of Earth Sciences 28 (2019) 920-938.
[22] Nazarinia A., Mortazavi M., Arvin M., Hu R., Zhao C., Poosti M., "U-Pb zircon dating, Sr-Nd isotope and petrogenesis of Sarduiyeh granitoid in SE of the UDMA, Iran: implication for the source origin and magmatic evolution", International Geology Review 62 (2020) 1796-1814.
[23] Atapour H., Aftabi A., "Petrogeochemical evolution of calcalkaline, shoshonitic and adakitic magmatism associated with Kerman Cenozoic arc porphyry copper mineralization, southeastern Iran: A review", Lithos 398 (2021) 106261.
[24] Mohamadzadeh Jahani N., ״Petrographic, geochemical and petrogensis study of the intrusive Jebalbarez Mountains (Southern city Nisa the dam BAM) (in Persian) ״, M.S.c thesis, Shahid Bahonar University of Kerman (2014).
[25] Yousefi S.J., ״Source and Evolution of Magmas and Ore Fluids in Kerver Porphyry Copper deposits, Kerman Copper Belt, Iran; Investigation of Factor Controlling the Productivity of Magmas and Ore Formation (in Persian) ״, PhD thesis, Shahid Bahonar University of Kerman (2018).
[26] Rasouli J., Ghorbani M., ״Copper mineralization, Alteration, zircon U-Pb geochronology and petrogenesis Delfard rocks (North West Jiroft) (in Persian)״, 110 (2019).
[27] Sepidbar S., ״Petrology, geochemistry and tectonic setting of western part of the jebal-e Barez granitoid complex, east of jiroft״, M.Sc thesis, Shahid Bahonar University of Kerman (2019).
[28] Behpour S., ״The origin, magma evolution and tectonic setting of southeast of Jebal-E-Barez granitoid, Bam, Kerman province (in Persian) ״, Iranian Journal of GEOSCIENCES 116 (2020).
[29] Jeshari M., ״Petrology, geochemistry and tectonic setting of middle part of the Jebal-e Barez granitoid complex, east of Jiroft״, M.Sc thesis, Shahid Bahonar University of Kerman (2020).
[30] Blundy J.D., Holland T.J., "Calcic amphibole equilibria and a new amphibole-plagioclase geothermometer", Contributions to Mineralogy and Petrology 104 (1990) 208-224.
[31] Arabzade Baniasadi M., Ghasemi H., Angiboust S., Rezaei Kahkhaei M., Minnaert-Thefo C., "Physicochemical conditions of crystallization based on the composition of amphibole-Plagioclase pair in the Gowd-e-Howz (Siah-Kuh) granitoid, Baft, Kerman (in Persian)", Iranian Journal of Petrology 14 (2024) 1-28.
[32] Leake B.E., Woolley A.R., Arps C.E., Birch W.D., Gilbert M.C., Grice J.D., Hawthorne F.C., Kato A., Kisch H.J., Krivovichev V.G., "Nomenclature of amphiboles; report of the Subcommittee on Amphiboles of the International Mineralogical Association Commission on new minerals and mineral names", Mineralogical Magazine 61 (1997) 295-310.
[33] Ale-Taha B., "Petrography and petrology of igneous rocks and related mineralization in the southeastern Bam (Jebal-e Barez) (in Persian)", PhD thesis, Islamic Azad University, Science and Research (2003).
[34] Dimitrijevic M.D., "Geology of Kerman region", Geological Survey of Iran, Report 52 (1973) 334.
[35] Atapour H., Aftabi A., "The geochemistry of gossans associated with Sarcheshmeh porphyry copper deposit, Rafsanjan, Kerman, Iran: implications for exploration and the environment", Journal of Geochemical Exploration 93 (2007) 47-65.
[36] Aftabi A., Atapour H., "Comments on “Arc magmatism and subduction history beneath the Zagros Mountains, Iran: A new report of adakites and geodynamic consequences”, by J. Omrani, P. Agard, H. Whitechurch, M. Bennoit, G. Prouteau, L. Jolivet", Lithos 113 (2009) 844-846.
[37] Hollister L.S., Grissom G., Peters E., Stowell H., Sisson V., “Confirmation of the empirical correlation of Al in hornblende with pressure of solidification of calc-alkaline plutons”, American Mineralogist, 72(3-4) (1987) 231-239
[38] Hammarstrom J.M., Zen E.A., "Aluminum in hornblende: an empirical igneous geobarometer", American Mineralogist 71 (1986) 1297-1313.
[39] Johnson M.C., Rutherford M.J., “Experimental calibration of an aluminum-in-hornblende geobarometer with application to Long Valley caldera (California) volcanic rocks”, Geology, 17(9) (1989) 837-841.
[40] Schmidt M.W., "Amphibole composition in tonalite as a function of pressure: An experimental calibration of the Al-in-hornblende barometer", Contributions to Mineralogy and Petrology 110 (1992) 304-310.
[41] Ridolfi F., "Amp-TB2: An updated model for calcic amphibole thermobarometry", Minerals 11 (2021) 324.
[42] Humphreys M.C.S., Blundy J.D., Sparks R.S.J., "Magma evolution and open-system processes at Shiveluch volcano: Insights from phenocryst zoning", Journal of Petrology 47 (2006) 2303-2334.
[43] Putirka K.D., "Amphibole thermometers and barometers for igneous systems and some implications for eruption mechanisms of felsic magmas at arc volcanoes", American Mineralogist 101 (2016) 841-858.
[44] Stöcklin J., "Structural history and tectonics of Iran: a review", AAPG Bulletin 52 (1968) 1229-1258.
[45] Dargahi S., Arvin M., Pan Y., Babaei A., "Petrogenesis of postcollisional A-type granitoids from the Urumieh–Dokhtar magmatic assemblage, Southwestern Kerman, Iran: constraints on the Arabian–Eurasian continental collision", Lithos 115 (2010) 190-204.
[46] Zhang S.H., Zhao Y., Song B., "Hornblende thermobarometry of the Carboniferous granitoids from the Inner Mongolia Paleo-uplift: implications for the tectonic evolution of the northern margin of North China block", Mineralogy and Petrology 87 (2006) 123-141.
[47] Papoutsa A., Pe-Piper G., "Geochemical variation of amphiboles in A-type granites as an indicator of complex magmatic systems: Wentworth pluton, Nova Scotia, Canada", Chemical Geology 384 (2014) 120-134.
[48] Martin R.F., "Amphiboles in the igneous environment", Reviews in Mineralogy and Geochemistry 67 (2007) 323-358.
[49] Ridolfi F., Renzulli A., Puerini M., "Stability and chemical equilibrium of amphibole in calc-alkaline magmas: An overview, new thermobarometric formulations and application to subduction-related volcanoes", Contributions to Mineralogy and Petrology 160 (2010) 45-66.
[50] Scaillet B., Macdonald R.A.Y., "Experimental constraints on the relationships between peralkaline rhyolites of the Kenya Rift Valley", Journal of Petrology 44 (2003) 1867-1894.
[51] Anderson J.L., Smith D.R., "The effect of temperature and oxygen fugacity on Al-in-hornblende barometry", American Mineralogist 80 (1995) 549-559.
[52] Moody J.B., Meyer D., Jenkins J.E., "Experimental characterization of the greenschist/amphibolite boundary in mafic systems", American Journal of Science 283 (1983) 48-92.
[53] Sial A., Ferreira V., Fallick A., Cruz M.J.M., "Amphibole-rich clots in calc-alkali granitoids in the Borborema province, northeastern Brazil", Journal of South American Earth Sciences 11 (1998) 457-471.
[54] Hawthorne F.C., Oberti R., Harlow G.E., Maresch W.V., Martin R.F., Schumacher J.C., Welch M.D., "Nomenclature of the amphibole super group", American Mineralogist 97 (2012) 2031-2048.
[55] Molina J.F., Moreno J.A., Castro A., Rodríguez C., Fershtater G.B., "Calcic amphibole thermobarometry in metamorphic and igneous rocks: New calibrations based on plagioclase/amphibole Al-Si partitioning and amphibole/liquid Mg partitioning", Lithos 232 (2015) 286-305.
[56] Stein E., Dietl C., "Hornblende thermobarometry of granitoids from the Central Odenwald (Germany) and their implications for the geotectonic development of the Odenwald", Mineralogy and Petrology 72 (2001) 207-285.
[57] Molina J.F., Scarrow J.H., Montero P.G., Bea F., “High-Ti amphibole as a petrogenetic indicator of magma chemistry: Evidence for mildly alkali hybrid melts during evolution of Variscan basic–ultrabasic magmatism of Central Iberia”, Contributions to Mineralogy and Petrology, 158, (2009), 69-98.
[58] Jiang C., An S., “On the chemical characteristics of calcific amphiboles from igneous rocks and their petrogenesis significance”, Journal of Mineralogy and Petrology, 3(1), 1-9.
[59] Coltorti M., Bonadiman C., Faccini B., Grégoire M., O'Reilly S.Y., Powell W., “Amphiboles from suprasubduction and intraplate lithospheric mantle”, Lithos, 99(1-2), (2007), 68-84.
[60] Helmy H., Ahmed A., El Mahallawi M., Ali S., “Pressure, temperature and oxygen fugacity conditions of calc-alkaline granitoids, Eastern Desert of Egypt, and tectonic implications”, Journal of African Earth Sciences, 38(3) (2004) 255- 268.
[61] Wones D.R., “Significance of the assemblage titanite+ magnetite+ quartz in granitic rocks’, American Mineralogist, 74(7-8), (1989) 744-749.
[62] Ishihara S., “The magnetite-series and ilmenite-series”, Mining Geology, 27, (1977) 293-305.
[63] Ridolfi F., Renzulli A., “Calcic amphiboles in calc-alkaline and alkaline magmas: Thermobarometric and chemometric empirical equations valid up to 1,130° C and 2.2 GPa”, Contributions to Mineralogy and Petrology, 163(5), (2012) 877-895. https://doi.org/101007/s00410-011-0704-6
[64] Simakin A.G., “Numerical modelling of the late stage of subduction zone transference after an accretion event”, Terra Nova, 26(1), (2014).22-28.
[65] Lisboa V.A.C., Conceição H., Rosa M.L.S., Marques G.T., Lamarão C.N., Lima A.L., "Amphibole crystallization conditions as record of interaction between ultrapotassic enclaves and monzonitic magmas in the Glória Norte stock, south of Borborema province", Brazilian Journal of Petrology 50 (2020) 1-10.
[66] Ernst W., Liu J., "Experimental phase-equilibrium study of Al-and Ti-contents of calcic amphibole in MORB—A semiquantitative thermobarometer", American Mineralogist 83 (1998) 952-969.
[67] Scaillet B., Evans B.W., "The 15 June 1991 eruption of Mount Pinatubo. I. Phase equilibria and pre-eruption P–T–f O2–f H2O conditions of the dacite magma", Journal of Petrology 40 (1999) 381-411.
)