Abdel-Rahman, A.F.M., 1994. Nature of biotites from alkaline, calc-alkaline, and peraluminous magmas. Journal of Petrology, 35: 525-541.
Abrecht, J., Hewitt, D.A., 1988. Experimental evidence on the substitution of tin in biotite. American Mineralogist, 73: 1275-1284.
Afshooni, S.Z., Mirnejad, H., Esmaeily, D., Asadiharoni, H., 2013. Mineral chemistry of hydrothermal biotite from the Kahang porphyry copper deposit (NE Isfahan), Central Province of Iran. Ore Geology Reviews, 54: 214-232.
Ashrafi, N., Jahangiri, A., Ameri, A., Hasebe, N., Eby, G.N., 2009. Biotite mineral chemistry of the Bozqush and Kaleybar alkaline igneous intrusions, NW Iran. Iranian Journal of Crystallography and Mineralogy, 17: 381-394 (in Persian with English abstract). http://ijcm.ir/article-1-568-fa.html
Ayati, F., Yavus, F., Noghreyan, M., Haroni, H.A., Yavuz, R., 2008. Chemical characteristics and composition of hydrothermal biotite from the Dalli porphyry copper prospect, Arak, central province of Iran. Mineralogy and Petrology, 94: 107-122.
Barbarin, B., 1990. Granitoids: Main petrogenetic classifications in relation to origin and tectonic setting. Geological Journal, 25: 227-238.
Boomeri, M., Mizuta, T., Ishiyama, D., Nakashima, K., 2006. Fluorine and chlorine in biotite from the Sarnowsar granitic rocks, northeastern Iran. Iranian Journal of Science and Technology, Transaction A30 (A1): 111-125.
Boomeri, M., Nakashima, K., Lentz, D.R., 2009. The Miduk porphyry Cu deposit, Kerman, Iran: a geochemical analysis of the potassic zone including halogen element systematic related to Cu mineralization processes. Journal of Geochemical Exploration, 103: 17-29.
Cottrell, E., Birner, S.K., Brounce, M., Davis, F.A., Waters, L.E., Kelley, K.A., 2021. Oxygen Fugacity Across Tectonic Settings. In: Moretti, R., Neuville, D.R. (Eds.), Magma Redox Geochemistry. American Geophysical Union, pp. 33-61. https://doi.org/10.1002/9781119473206.ch3
Deer, W.A., Howie, R.A., Zussman, J., 2013. An Introduction to the Rock Forming Mineral. Third Longman Editions, 498 pp.
Feng, Y., Deng, C., Xiao, B., Gong, L., Yin, R., Sun, D., 2021. Biotite geochemistry and its implication on the temporal and spatial difference of Cu and Mo mineralization at the Xiaokele porphyry Cu-Mo deposit, NE China. Ore Geology Reviews, 139: 104508.
https://doi.org/10.1016/j.oregeorev.2021. 104508
Foley, S.F., Prelevic, D., Rehfeldt, T., Jacob, D.E., 2013. Minor and trace elements in olivines as probes into early igneous and mantle melting processes. Earth and Planetary Science Letters, 363: 181-191. 324 Ashrafi et al.
Foster, M.D., 1960. Interpretation of the composition of lithium micas. US Geological Survey, 354: 11-49.
Heinrich, E.W., 1946. Studies in the mica group; the biotite-phlogopite series. American Journal of Science, 244(12): 836-848.
Huang, Y., Nakatani, T., Nakamura, M., Mccammon, C., 2019. Saline aqueous fluid circulation in mantle wedge inferred from olivine wetting properties. Nature Communications, 10: 1-10.
Janousek, V., Farrow, C.M., Erban, V., 2006. Interpretation of whole-rock geochemical data in igneous geochemistry: introducing Geochemical Data Toolkit (GCDkit). Journal of Petrology, 47: 1255-1259.
Kovalenko, V.I., Naumov, V.B., Girnis, A.V., Dorofeeva, V.A., Yarmolyuk, V.V., 2007. Average compositions of magmas and mantle sources of mid-ocean ridges and intraplate oceanic and continental settings estimated from the data on melt inclusions and quenched glasses of basalts. Petrology, 15(4): 335-368.
Liu, J.Q., Chen, L.H., Wang, X.J., Zhong, Y., Yu, X., Zeng, G., Erdmann, S., 2017. The role of meltrock interaction in the formation of Quaternary high-MgO potassic basalt from the Greater Khingan Range, northeast China. Journal of Geophysical Research: Solid Earth, 122: 262-280.
Moshefi, P., Hosseinzadeh, M.R., Moayyed, M., Lentz, D.R., 2020. Distinctive geochemical features of biotite types from the subeconomic Sonajil porphyry-type Cu deposit, northwestern Iran:implications for analysis of porphyry copper deposit mineralization potential. Journal of Geochemical Exploration, 214: 106543.
Mullen, E.D., 1983. MnO/TiO2/P2O5: A minor element discriminant for basaltic rocks of oceanic environments and its implications for petrogenesis. Earth and Planetary Science Letters, 62: 53-62.
Munoz, J.L., 1984. F-OH and Cl-OH exchange in mica with application to hydrothermal ore deposits. Reviews in Mineralogy, 13: 469-493.
Munoz, J.L., 1992. Calculation of HF and HCl fugacities from biotite compositions: revised equations. Geological Society of America Abstracts with Programs, 24: p. 221.
Nachit, H., Ibhi, A., Abia, E.H., Ohoud, M.B., 2005. Discrimination between primary magmatic biotites, reequilibrated biotites and neoformed biotites. Comptes Rendus Geoscience, 337: 1415-1420.
Nachit, H., Razafimahefa, N., Stussi, J.M., Caron, J.P., 1985. Composition chimique des biotites et typologie magmatique des granitoïdes. Comptes rendus hebdomadaires des séances de l'Académie des sciences, 301: 813-818.
Patiño Douce, A.E., 1993. Titanium substitution in biotite: an empirical model with applications to thermometry, O2 and H2O barometries, and consequences for biotite stability. Chemical Geology, 108: 133-162.
Rieder, M., Cavazzini, G., D'Yakonov, Y.S., Frank-Kamenetskii, V.A., Gottardi, G., Guoggenheim, S., Koval, P.V., Muller, G., Neiva, A.M.R., Radoslovich, E.W., Robert, J.L., Sassi, F.P., Takeda, H., Weiss, Z., Wones, D.R., 1998. Nomenclature of the micas. Canadian Mineralogist, 36: 41-48.
Saha, R., Upadhyay, D., Mishra, B., 2021. Discriminating tectonic setting of igneous rocks using biotite major element chemistry−A Machine Learning Approach. Geochemistry, Geophysics, Geosystems, 22(11): e2021GC010053 https://doi.org/10.1029/2021GC010053
Samadi, R., Torabi, G., Kawabata, H., Miller, N.R., 2021. Biotite as a petrogenetic discriminator: Chemical insights from igneous, meta-igneous and meta-sedimentary rocks in Iran. Lithos 386-387, 106016.
Schmidt, M.W., Jagoutz, O., 2017. The global systematics of primitive arc melts. Geochemistry, Geophysics, Geosystems, 18: 2817-2854
Shabani, A.A.T., Lalonde, A.E., Whalen, J.B., 2003. Composition of biotite from granitic rocks of the Canadian Appalachian orogen: A potential tectonomagmatic indicator? Canadian Mineralogist, 41(6): 1381-1396.
Stussi, J.M., Cuney, M., 1996. Nature of biotites from alkaline, calc-alkaline and peraluminous magmas by Abdel-Fattah M. Abdel-Rahman: a comment. Journal of Petrology, 37: 1025-1029.
Ueki, K., Iwamori, H., 2014. Thermodynamic calculations of the polybaric melting phase relations of spinel lherzolite. Geochemistry, Geophysics, Geosystems, 15: 5015-5033.
Van Middelaar, W.T., Keith, J.D., 1990. Mica chemistry as an indicator of oxygen and halogen fugacities in the Can Tung and other W-related granitoids in the North American Cordillera. In: Stein, H.J., Hannah, J.L. (Eds.), Ore-bearing Granite Systems; Petrogenesis and Mineralizing Geopersia 2024, 14(2): 307-325 325 Process. Geological Society of America, Special Paper 246: 205-220.
Wones, D.R., Eugster, H.P., 1965. Stability of biotite: Experiment, theory, and application. American Mineralogist, 50: 1228-1272.
Zhang, W., Lentz, D.R., Thorne, K.G., McFarlane, C., 2016. Geochemical characteristics of biotite from felsic intrusive rocks around the Sisson Brook W-Mo-Cu deposit, west central New Brunswick: an indicator of halogen and oxygen fugacity of magmatic systems. Ore Geology Reviews, 77: 82-96.
)