[1] Arian M., Noroozpour H., “Tectonic Geomorphology of Iran’s Salt Structures”, Open Journal of Geology (2015) 5(02): 61-79.
[2] Talbot C.J., “Extrusions of Hormuz salt in Iran”, Geological Society, London, Special Publications (1998) 143: 315-334.
[3] Ghazban F., Al-Aasam I.S. “Hydrocarbon-induced diagenetic dolomite and pyrite formation associated with the Hormoz Island salt dome, offshore Iran”, Journal of Petroleum Geology (2010) 33: 183-196.
[4] Hassanlouei B.T., Rajabzadeh M.A., “Iron ore deposits associated with Hormuz evaporitic series in Hormuz and Pohl salt diapirs, Hormuzgan province, southern Iran”, Journal of Asian Earth Sciences (2019) 172: 30-55.
[5] Faramarzi N.S., Jamshidibadr M., Heuss-Assbichler S., Borg G., “Mineral chemistry and fluid inclusion composition as petrogenetic tracers of iron oxide-apatite ores from Hormuz Island, Iran”, Journal of African Earth Sciences (2019) 155: 90-108."
[6] Abdelnasser A., Kumral M., Zoheir B., Karaman M. and Weihed P., “REE geochemical characteristics and satellite- based mapping of hydrothermal alteration in Atud gold deposit, Egypt”, Journal of African Earth Sciences (2018) 145: 317- 330.
[7] Bea F., Fershtater G., Corretge L.G., "The geochemistry of phosphorus in granite and the effect of aluminum", Lithos (1992) 29: 43-45.
[8] Frietsch R., Perdahl J.A., “Rare earth elements in apatite and magnetite in Kiruna-type iron ores and some other iron ore types”, Ore Geology Reviews (1995) 9(6): 489-510.
[9] Fakhari M., “Bandarabbas geological compilation map. M. Fakhari Ph. D thesis uder supervision of S”, Shahriyary, Islamis Azad unversity (1994).
[10] Rostami A., Bazamad M., Haj Alilou B., Moazzen M., “Investigation of Rare earth elements in apatite of Hormuz salt dome (in Persian)”, Journal of Economic Geology (2014) 6: 71-85.
[11] Alian F., Bazamad M., “Petrography of Zendan salt dome (Hara), Bandar Lengeh”, In 6th Symposium of Iranian society of Economic Geology, Sistan and Baluchestan University, Zahedan, Iran (in Persian), (2014).
[12] Ghasemi A. and Talbot C.J.," A new tectonic scenario for the Sanandaj-Sirjan Zone (Iran)", Journal of Asian Earth Sciences )2006) 26: 683-693
[13] Alavi M., “Structures of the Zagros fold-thrust belt in Iran”, American Journal of Science (2007) 307: 1064-1095. DOI: 10.2475/09.2007.02
[14] Heydari E., “Tectonics versus eustatic control on supersequences of the Zagros Mountains of Iran”, Tectonophysics (2008) 451: 56–70. DOI: 10.1016/j.tecto.2007.11.046.
[15] Alavi M., “Regional stratigraphy of the Zagros fold-thrust belt of Iran and its proforeland evolution”, American Journal of Science (2004) 304: 1–20. DOI: 10.2475/ajs.304.1.1.
[16] Richardson R.K., “Die Geologie und die Salzdoms in sud-Westhichen des Persischen Golfes: Verh. Naturh-med”, Ver Teile Heidelberg D. S 15 (1972).
[17] Jafari Sadr A.R., “Geology and petrology of the complex of igneous rocks and the transformation of the salt dome of Gachin (Bandar Abbas)”, MSc thesis, University of Tehran (2001).
[18] Sun S.S, Mc Donough W.F., "Chemical and isotopic systematics of oceanic basalts: implications for mantle composition and processes", Geological Society, London, Special Publications (1989) 42 (1): 313-345.
[19] Temizel R., Arslan M., Ruffet G., Peucat J.J., "Petrochemistry, geochronology and Sr-Nd isotopic systematics of the Tertiary collisional and post-collisional volcanic rocks from the Ulube (Ordu) area, eastern Pontide, NE Turkey implications for extension-related originand mantle source characteristics", Lithos (2012) 128: 126–147.
[20] Biabangard H., Rigie S., Soloke H.R., “Petrology, geochemistry and origion of Rigmalak granite, southeast of Zahedan”, Iranian Journal of Crystallography and Mineralogy (2019) 27: 839-854.
[21] Aldanmaz E., Pearce J.A., Thirlwall M.F., Mitchell J.G., "Petrogenetic evolution of late Cenozoic, post-collision volcanism in western Anatolia, Turkey", Journal of Volcanology and Geothermal Research (2000) 102: 67-95.
[22] Zareie Sahamiye R., Ebrahimi S., “Petrology, mineral chemistry and tectonomagmatic environment of volcanic rocks northeast of Farmahin (North of Arak)”, (in Persian) (2014) 6: 375-392.
[23] Motamedi Blanford N.T., “Note on the geological formation seen along the coasts of Baluchistan and Persia from Karachi to the head of Persian Gulf”, Geological Survey of India (1872) 5: 5- 41.
[24] Kamber B.S., Ewart A., Collerson K.D., Bruce M.C. and McDonald G.D., “Fluid-mobile trace element constraints on the role of slab melting and implications for Archaean crustal growth models”, Contributions to Mineralogy and Petrology (2002) 144: 38- 56.
[25] You C.F., Catillo P.R., Gieskes J.M., Chan L.H., Spivack A.J., "Trace element behavior in hydrothermal experiments: Implications for fluid processes at shallow depth in subduction zones”, Earth and Planetary Science Letters (1996) 140; 41-52.
[26] Wilson M, "Igneous petrogenesis a global tectonic approach", Department of earth Science, University of leeds, (1989) 466.
[27] Rollinson H. R.," using Geochemical Data: Evaluation, Presentation, Interpretation", Routledge (2014).
[28] Pearce J.A., “Trace element characteristics of lavas from destructive plate boundaries”, In: Thorpe, R.S. (Ed.), Andesites: Orogenic Andesites and Related Rocks. John Wiley and Sons, Chichester, England (1982) 525–548.
[29] Pearce J.A., Norry M.J., "Petrogenetic implication of Ti, Zr, Y and Nb variations in volcanic rocks", Contribution to Mineralogy and Petrology (1979) 69: 33- 47.
[30] Kurkcuoglu B., "Geochemistry and petrogenesis of basaltic rocks from the Develidag volcanic complex, Central Anatolia, Turkey", Journal of Asian Earth Sciences (2010) 37: 42-51.
[31] Pearce J.A., Harris N.B.W., Tindle A.G., “Trace element discrimination diagramsfor the tectonic interpretation of granitic rocks”, Journal of Petrology (1984) 25(4): 956-983.
[32] Schandl E.S., Gorton M.P., “Application of high field strength elements to discriminate tectonic settings in VMS environments”, Economic Geology (2002) 97: 629–642.
[33] Pearce J.A., "Role of the sub-continental lithosphere in magma genesis at active continental margins", In: Hawkesworth, C.J.,. Nurry, M.L. (Eds.), Continental basalts and Mantle Xenoliths. Shiva, Nantwich (1983) 230-249.
[34] Elburg M.A., Bergen M.V., Hoogewerff J., Foden J., Vroon P., Zulkarnain I., Nasution A. "Geochemical trends across an arc-continent collision zone: magma sources and slab-wedge transfer processes below the Pantar Strait volcanoes", Indonesia. Geochemica et Cosmochimica Acta (2002) 66: 2771–2789
[35] Boynton W.V., “Cosmochemistry of the rare earth elements: meteorite studies”, In Developments in geochemistry, Elsevier (1984) 2: 63-114.
[36] Barati M., Gholipour M., “Study of behavior of Rare Earth Elements, fluid inclusions, and stable isotopes of oxygen and sulfur in Zafar Abad skarn iron ore deposit, Northwest of Divandareh, Kurdistan Province”, Journal of Economic Geology (2014) 2: 35-57.
[37] Kuscu G.G., Geneli F., "Review of post-collisional volcanism in the Central Anatolian Volcanic Province (Turkey), with special reference to the Tepekoy Volcanic Complex”, International Journal of Earth Sciences (2010) 99 (3): 593-621.
[38] Sirvastava R. K., Singh R.K., “Trace element geochemistry and gemesise of Precambrian sub-alkaline mafic dikes from the centeral indian craton”. evidence for mantle metasomatism: Asan Earth Science (2004) 23: 373-389.
[39] Ndjigui P.D., Bilong P., Bitom D., Dia A.,"Mobilization and redistribution of major and trace elements in two weathering profiles developed on serpentinites in the Lomié ultramafic complex, South-East Cameroon", Journal of African Earth Sciences (2008) 50: 305-328.
[40] Edfelt A., “The Tjarrojakka Apatite-Iron and Cu (-Au) Deposits, Northern Sweden”, Thesis for the Degree of Doctor of Philosophy (2007).
[41] Henderson P. ed., “Developments in Geochemistry: Rare Earth Element Geochemistry”, Elsevier (1984).
[42] Wilkinson J.J., Eyre S.L., Boyce A.J., "Oreforming processes in Irish-type carbonate-hosted Zn-Pb deposits: evidence from mineralogyدchemistry and isotopic composition of sulfides at the Lisheen Mine", Economic Geology (2005) 100: 63-86.
[43] Richards J.P., Spell T., Rameh E., Razique A., Fletcher T., “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 (2012) 107: 295–332.
[44] Zarasvandi A., Rezaei M., Tashi M., Fereydouni Z., Saed M., “Comparison of geochemistry and porphyry copper mineralization efficiency in granitoids of the Sanandaj-Sirjan and Urumieh-Dokhtar zones; using rare earth elements geochemistry”, (in Persian), Journal of Economic Geology (2019) 11: 1-32.
[45] Chen B., Jahn B.M., Wei C., “Petrogenesis of Meso zoic granitoidsin the Dabie UHP complex, Central China: trace element and Nd–Sr isotope e vidence”, Lithos (2002) 60: 67–88.
[46] Sha L.K., Chappell B.W., “Apatite chemical composition, determined by electron microprobe and laser-ablation inductively coupled plasma mass spectrometry, as a probe into granite petrogenesis”, Geochimica et Cosmochimica Acta (1999) 63 (22): 3861-3881.
[47] Mehraban Z., Shafiei Bafti B., Shamanian G.H., “Rare Earths in fluorite deposit of Elika Formation (East of Mazandaran Province)”, Journal of Economic Geology (2016) 8: 201-221.
[48] Faramarzi N.S, Amini S., Mortazavi S.M., “Study of quartz and apatite fluids in Hormoz Island (southern Iran)”, 18th Conference of the Geological Society of Iran, Tehran, (2014) https://civilica.com/doc/391352.
[49] Whitney, D.L., Evans, B.W., “Abbreviations for names of rock-forming minerals”, American mineralogist, (2010) 95(1), 185-187. https://doi.org/10.2138/am.2010.3371.
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