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• Grapes, R. Pyrometamorphism, 2nd ed.; Springer: Berlin/Heidelberg, Germany, 2010; pp. 1–364.
• Reverdatto, V.V. The Facies of Contact Metamorphism; Sobolev, V.S., Ed.; Nedra: Moscow, Russia, 1970; pp. 1–263. (In Russian).
• Piret, R. Minéralogie et Géochimie des Skarns de Haute Température des Régions de Măgureaua Vaţei et de Cornet Hill (Monts Apuseni). Master’s Thesis, Université Catholique de Louvain, Louvain-la-Neuve, Belgium, 1997.
• Pascal, M.-L.; Fonteilles, M.; Verkaeren, J.; Piret, R.; Marincea, Ş. The melilite-bearing high-temperature skarns of the Apuseni Mountains, Carpathians, Romania. Can. Mineral. 2001, 39, 1405–1434.
• Ştefan, A.; Istrate, G.; Medeşan, A. Gehlenite in calc-skarns from the Măgureaua Vaţei—Cerboaia (Apuseni Mountains—Romania). Rev. Roum. Géol. Géophys. Géogr. Sér. Géol. 1978, 22, 155–160.
• Marincea, Ş.; Dumitraş, D.G.; Ghineţ, C.; Fransolet, A.-M.; Hatert, F.; Rondeux, M. Gehlenite from three occurrences of high-temperature skarns, Romania: New mineralogical data. Can. Mineral. 2011, 49, 1001– 1014.
• Marincea, Ş.; Dumitraş, D.G. Monticellite and hydroxylellestadite in high-temperature skarns from Romania. Acta Mineral.-Petrogr. Abstr. Ser. 2003, 1, 68.
• Pascal, M.-L.; Katona, I.; Fonteilles, M.; Verkaeren, J. Relics of high-temperature clinopyroxene on the join Di-CaTs with up to 72 mol.% Ca(Al, Fe3+)AlSiO6 in the skarns of Ciclova and Măgureaua Vaţei, Carpathians, Romania. Can. Mineral. 2005, 43, 857–881.
• Takéuchi, Y.; Haga, N.; Umizu, S.; Sato, G. The derivative structure of silicate garnets in grandite. Z. Kristallogr. 1982, 158, 53–99.
• Shtukenberg, A.G.; Punin, Y.O.; Frank-Kamenetskaya, O.V.; Kovalev, O.G.; Sokolov, P.B. On the origin of anomalous birefringence in grandite garnets. Mineral. Mag. 2001, 65, 445–459.
• Krivovichev, S.V.; Yakovenchuk, V.N.; Panikorovskii, T.L.; Savchenko, E.E.; Pakhomovsky, Y.A.; Mikhailova, Y.A.; Selivanova, E.A.; Kadyrova, G.I.; Ivanyuk, G.Y. Nikmelnikovite, Ca12Fe2+Fe3+3Al3(SiO4)6(OH)20, a new mineral from Kovdor massif (Kola peninsula, Russia). Dokl. Earth Sci. 2019, 488, 1200–1202.
• Henmi, C.; Kawahara, A.; Henmi, K.; Kusachi, I.; Takéuchi, Y. The 3T, 4T and 5T polytypes of wollastonite from Kushiro, Hiroshima Prefecture, Japan. Am. Mineral. 1983, 68, 156–163.
• Gnos, E.; Armbruster, T. Relationship among metamorphic grade, vesuvianite “rod polytypism”, and vesuvianite composition. Am. Mineral. 2006, 91, 862–870.
• Ohkawa, M.; Armbruster, T.; Galuskin, E. Structural investigation of low-symmetry vesuvianite collected from Tojyo, Hiroshima, Japan: Implications for hydrogarnet-like substitutions. J. Mineral. Petrol. Sci. 2009, 104, 69–76.
• Marincea, Ş.; Bilal, E.; Verkaeren, J.; Pascal, M.L.; Fonteilles, M. Superposed parageneses in the spurrite-, tilleyite-, and gehlenite-bearing skarns from Cornet Hill, Apuseni Mountains, Romania. Can. Mineral. 2001, 39, 1435–1453.
• Marincea, Ş.; Dumitraş, D.G.; Călin, N.; Anason, A.M.; Fransolet, A.-M.; Hatert, F. Spurrite, tilleyite and associated minerals in the exoskarn zone from Cornet Hill (Metaliferi Massif, Apuseni Mountains, Romania). Can. Mineral. 2013, 51, 359–375.
• Marincea, Ş.; Dumitraş, D.G.; Ghineţ, C.; Bilal, E. The occurrence of high-temperature skarns from Oraviţa (Banat, Romania): A mineralogical overview. Can. Mineral. 2015, 53, 511–532.
• Cioflica, G.; Vlad, Ş. The correlation of the Laramian metallogenetic events belonging to the Carpatho-Balkan area. Rev. Roum. Géol. Géophys. Géogr. Sér. Géol. 1973, 17, 217–224.
• Săndulescu, M.; Kräutner, H.; Borcoş, M.; Năstăseanu, S.; Patrulius, D.; Ştefănescu, M.; Ghenea, C.; Lupu, M.; Savu, H.; Bercia, I.; et al. Geological Map of Romania, Scale 1:1,000,000; Institute of Geology and Geophysics: Bucharest, Romania, 1978.
• Berza, T.; Constantinescu, E.; Vlad, Ş.N. Upper Cretaceous magmatic series and associated mineralizations in the Carpathian-Balkan orogen. Res. Geol. 1998, 48, 291–306.
• Ciobanu, C.L.; Cook, N.J.; Stein, H. Regional setting and geochronology of the Late Cretaceous Banatitic Magmatic and Metallogenetic Belt. Miner. Depos. 2002, 37, 541–567.
• Zimmermann, A.; Stein, H.; Hannah, J.; Koželj., D.; Bogdanov, K.; Berza, T. Tectonic configuration of the Apuseni-Banat-Timok-Srednogorie belt, Balkans-Southern Carpathians, constrained by high precision Re-Os molybdenite ages. Miner. Depos. 2008, 43, 1–21.
• Ştefan, A.; Lazăr, C.; Berbeleac, I.; Udubaşa, G. Evolution of the Banatitic magmatism in the Apuseni Mts. and the associated metallogenesis. D. S. Inst. Geol. Geofiz. 1988, 72, 195–213.
• Săbău, G.; Negulescu, E. Peritectic metasomatism and agpaitic line of descent in the endocontact zone of the Măgureaua Vaţei (MV) intrusives (Apuseni Mts.). In Proceedings of the V. M. Goldschmidt Conference 2014, Sacramento, Program and Abstracts, Sacramento, CA, USA, 8–13 June 2014; Volume 24, p. 2155.
• Ştefan, A.; Roşu, E.; Andăr, A.; Robu, L.; Robu, N.; Bratosin, I.; Grabari, G.; Stoian, M.; Vâjdea, E.; Colios, E. Petrological and geochemical features of banatitic magmatites in Northern Apuseni Mountains. Rom. J. Petrol. 1992, 75, 97–110.
• Bleahu, M.; Soroiu, M.; Catilina, R. On the Cretaceous tectonic–magmatic evolution of the Apuseni Mountains as revealed by K–Ar dating. Rev. Roum. Phys. 1984, 29, 123–130.
• Lupu, M.; Avram, E.; Antonescu, E.; Dumitrică, P.; Lupu, D.; Nicolae, I. The Neojurassic and the Cretaceous of the Drocea Mts.: The stratigraphy and the structure of an ensialic marginal basin. Rom. J. Tecton. Reg. Geol. 1993, 75, 53–66.
• Pouchou, J.L.; Pichoir, F. PAP φ (ρZ) procedure for improved quantitative microanalysis. In Microbeam Analysis; Armstrong, J.T., Ed.; San Francisco Press: San Francisco, CA, USA, 1985; pp. 104–106.
• Appleman, D.E.; Evans, H.T., Jr. Indexing and least-squares refinement of powder diffraction data. US Geol. Surv. Comput. Contrib. 1973, 20, 60.
• Benoit, P.H. Adaptation to microcomputer of the Appleman-Evans program for indexing and least-squares refinement of powder-diffraction data for unit-cell dimensions. Am. Mineral. 1987, 72, 1018–1019.
• Agilent Technologies. Xcalibur CCD System, CrysAlis Software System; Agilent Technologies: Yarnton, Oxfordshire, UK, 2012.
• Sheldrick, G.M. A short history of SHELX. Acta Crystallogr. 2008, A64, 112–122.
• Dolomanov, O.V.; Bourhis, L.J.; Gildea, R.J.; Howard, J.A.K.; Puschmann, H. OLEX2: A complete structure solution, refinement and analysis program. J. Appl. Cryst. 2009, 42, 339–341.
• Strunz, H.; Nickel, E.H. Strunz Mineralogical Tables, Collection, 9th ed.; Schweizerbart’sche Verlangsbuchhandlung: Berlin/Stuttgart, Germany, 2001; pp. 1–870.
• Whitney, D.L.; Evans, B.W. Abbreviations for names of rock-forming minerals. Am. Mineral. 2010, 95, 185– 187.
• Louisnathan, S.J. Refinement of the crystal structure of a natural gehlenite, Ca2Al(Al,Si)2O7. Can. Mineral. 1971, 10, 822–837.
• Armbruster, T.; Birrer, J.; Libowitzky, E.; Beran, A. Crystal chemistry of Ti-bearing andradites. Eur. J. Mineral. 1998, 10, 907–921.
• Droop, G.T.R. A general equation for estimating Fe3+ concentrations in ferromagnesian silicates and oxides from microprobe analyses, using stoichiometric criteria. Mineral. Mag. 1987, 51, 431–435.
• Tilley, C.E. The zoned contact-skarns of the Broadford area, Skye: A study of boron-fluorine metasomatism in dolomites. Mineral. Mag. 1951, 29, 622–666.
• Sabine, P.A.; Young, B.R. Metamorphic processes at high temperature and low pressure: The petrogenesis of the metasomatized and assimilated rocks of Carneal, Co. Antrim. Phil. Trans. R. Soc. Lond. 1975, 280, 225–269.
• Hesse, K.-F. Refinement of the crystal structure of wollastonite-2M (parawollastonite). Z. Kristall. 1984, 168, 93–98.
• Nikishov, K..; Nikishova, L.V. The possibility of reaction between olivine and monticellite. Geochem. Int. 1966, 3, 1200–1206.
• Deer, W.A.; Howie, R.A.; Zussman, J. Rock-Forming Minerals 1A Orthosilicates, 2nd ed.; Longman Ed.: London, UK; New York, NY, USA, 1982; pp. 1–919.
• Sharp, Z.D.; Hazen, R.M.; Finger, L.W. High-pressure crystal chemistry of monticellite, CaMgSiO4. Am. Mineral. 1987, 72, 748–755.
• Groat, L.A.; Hawthorne, F.C.; Ercitt, T.S. The chemistry of vesuvianite. Can. Mineral. 1992, 30, 19–48.
• Passaglia, E.; Rinaldi, R. Katoite, a new member of the Ca3Al2(SiO4)3-Ca3All2(OH)12 series and a new nomenclature for the hydrogrossular group of minerals. Bull. Minéral. 1984, 107, 605–618.
• Bailey, S.W.; Lister, J.S. Structures, compositions, and X-ray diffraction identification of dioctahedral chlorites. Clays Clay Miner. 1989, 37, 193–202.
• Weiss, Z. Interpretation of chemical composition and X-ray diffraction patterns of chlorites. Geol. Carpathica 1991, 42, 93–104.
• Bailey, S.W. (Ed.) Chlorites: Structures and crystal chemistry. In Hydrous Phyllosilicates; Reviews in Mineralogy; Mineralogical Society of America: Madison, WI, USA, 1988; Volume 19, 347–398.
• Hey, M.H. A new review of the chlorites. Mineral. Mag. 1954, 30, 277–292.
• Wicks, F.J.; Zussman, J. Microbeam X-ray diffraction patterns of the serpentine minerals. Can. Mineral. 1975, 13, 244–258.
• Whittaker, E.J.W.; Zussman, J. The characterization of serpentine minerals by X-ray diffraction. Mineral. Mag. 1956, 31, 107–126.
• Whittaker, E.J.W.; Wicks, F.J. Chemical differences among the serpentine “polymorphs”. Am. Mineral. 1970, 55, 1025–1047.
• Wada, K.; Yamada, H. Hydrazine intercalation-intersalation for differentiation of kaolin minerals from chlorites. Am. Mineral. 1968, 53, 334–339.
• Franco, F.; Ruiz Cruz, M.D. A comparative study of the dehydroxylation process in untreated and hydrazine-deintercalated dickite. J. Therm. Anal. Calorim. 2006, 85, 369–375.
• Bish, D.L.; Johnston, C.T. Rietveld refinement and Fourier-transform infrared spectroscopic study of the dickite structure at low temperature. Clays Clay Miner. 1993, 41, 297–304.
• Merlino, S. Okenite, Ca10Si18O46·18H2O: The first example of a chain sheet silicate. Am. Mineral. 1983, 68, 614–622.
• Effenberger, H.; Mereiter, K.; Zemann, J. Crystal structure refinements of magnesite, calcite, rhodochrosite, siderite, smithsonite and dolomite, with discussion of some aspects of the stereochemistry of calcite-type carbonates. Z. Kristallogr. 1981, 156, 233–243.
• McConnell, J.D.C. A chemical, optical and X-ray study of scawtite from Ballycraigy, Larne, N. Ireland. Am. Mineral. 1955, 40, 510–514.
• Bentor, I.K.; Gross, S.; Heller, L. Some unusual minerals from the “Mottled Zone” complex, Israel. Mineral. Mag. 1963, 48, 924–930.
• Ruiz Cruz, M.D.; Moreno Real, L. Practical determination of allophane and synthetic alumina and iron oxide gels by X-ray diffraction. Clays Clay Miner. 1991, 26, 377–387.
• Pertsev, N.N. Skarns as magmatic and postmagmatic formations. Int. Geol. Rev. 1974, 16, 572–582.
• Pertsev, N.N. High-T Metamorphism and Metasomatism in Carbonate Rocks; Nauka: Moscow, Russia, 1977; pp. 1–256. (In Russian).