Phasengleichgewichte und Mineralreaktionen in metamorphen Gesteinen

• Bucher K, Frey M (2002) Petrogenesis of metamorphic rocks. Springer Berlin Heidelberg New York

  Google Scholar 

• Ernst WG (1976) Petrologic phase equilibria. Freeman, San Francisco

  Google Scholar 

• Miyashiro A (1994) Metamorphic petrology. UCL Press, London

  Google Scholar 

• Seifert F (1978) Bedeutung und Nachweis von thermodynamischem Gleichgewicht und die Interpretation von Ungleichgewichten. Fortschr Mineral 55:111–134

  Google Scholar 

• Spear FS (1993) Metamorphic phase equilibria and pressure-temperature-time paths. Mineral Soc America, Washington, DC

  Google Scholar 

• Will TM (1998) Phase equilibria in metamorphic rocks — thermodynamic background and petrological applications. Springer, Berlin Heidelberg New York

  Google Scholar 

• Yardley BWD (1989) An introduction to metamorphic petrology. Longman, Burnt Mill, Harlow, England

  Google Scholar 

Zitierte Literatur

• Berman RG (1988) Internally consistent thermodynamic data for minerals in the system Na₂O-K₂O-CaO-MgO-FeO-Fe₂O₃-Al₂O₃-SiO₂-TiO₂-H₂O-CO₂. J Petrol 29:445–522

  Google Scholar 

• Bohlen SR, Montana A, Kerrick DM (1991) Precise determinations of equilibria kyanite ⇌ sillimanite and kyanite ⇌ andalusite and a revised triple point for Al₂SiO₅ polymorphs. Am Mineral 76:677–680

  Google Scholar 

• Chatterjee ND (1970) Synthesis and upper stability of paragonite. Contrib Mineral Petrol 27:244–257

  Article  Google Scholar 

• Chatterjee ND (1972) The upper stability limit of the assemblage paragonite + quartz and its natural occurrences. Contrib Mineral Petrol 34:288–303

  Article  Google Scholar 

• Chatterjee ND, Johannes W (1974) Thermal stability and standard thermodynamic properties of synthetic 2M₁-muscovite, K[AlSi₃O₁₀(OH)₂]. Contrib Mineral Petrol 48:89–114

  Article  Google Scholar 

• Chernosky JV Jr., Day HW, Caruso LJ (1985) Equilibria in the system MgO-SiO₂-H₂O: Experimental determination of the stability of Mg-anthophyllite. Am Mineral 70:223–236

  Google Scholar 

• Cho M, Maruyama S, Liou JG (1987) An experimental investigation of heulandite-laumontite equilibrium at 1000 to 2 000 bar P _fluid. Contrib Mineral Petrol 97:43–50

  Article  Google Scholar 

• England PC, Thompson AB (1984) Pressure-temperature-time paths of regional metamorphism. Part I: Heat transfer during the evolution of regions of thickened continental crust. J Petrol 25:894–928

  Google Scholar 

• Eugster HP (1957) Heterogeneous reactions involving oxidation and reduction at high temperatures. J Chem Phys 26:1760–1761

  Article  Google Scholar 

• Evans BW, Johannes W, Oterdoom H, Trommsdorff V (1976) Stability of chrysotile and antigorite in the serpentinite multisystem. Schweiz Mineral Petrogr Mitt 56:79–93

  Google Scholar 

• Goldschmidt VM (1911) Die Kontaktmetamorphose im Kritianiagebiet. Oslo Vidensk Skr, I Math-Nat K1, no 11

  Google Scholar 

• Greenwood HJ (1961) The system NaAlSi₂O₆-H₂O-argon: Total pressure and water pressure in metamorphism. J Geophys Res 66:3923–3946

  Google Scholar 

• Greenwood HJ (1967) Mineral equilibria in the system MgO-SiO₂-H₂O-CO₂. In: Abelson PH (ed) Researches in Geochemistry. pp 542–567, Wiley, New York

  Google Scholar 

• Gruner BB (2000) Metamorphoseentwicklung im Kaokogürtel, NW-Namibia: Phasenpetrologische und geothermobarometrische Untersuchungen panafrikanischer Metapelite. Freiberger Forschungshefte C486:221 pp

  Google Scholar 

• Harker RI, Tuttle OF (1956) Experimental data on the P _CO2-T curve for the reaction calcite + quartz = wollastonite + carbon dioxide. Am J Sci 254:239–256

  Google Scholar 

• Hemley JJ (1967) Stability relations of pyrophyllite, andalusite, and quartz at elevated pressures and temperatures. Am Geophys Union Trans 48:224

  Google Scholar 

• Holdaway MJ (1971) Stability of andalusite and the aluminum silicate phase diagram. Am J Sci 271:97–131

  Article  Google Scholar 

• Holdaway MJ, Mukhopadhyay B (1993) A reevaluation of the stability relations of andalusite: Thermochemical data and phase diagram for the aluminum silicates. Am Mineral 78:298–315

  Google Scholar 

• Holland TJB, Powell R (1985) An internally consistent thermodynamic dataset with uncertainties and correlations: 2. Data and results. J Metam Geol 3:343–370

  Google Scholar 

• Holland TJB, Powell R (1990) An enlarged and updated internally consistent thermodynamic dataset with uncertainties and correlations: The system K₂O-Na₂O-CaO-MgO-MnO-FeO-Fe₂O₃-Al₂O₃-TiO₂-SiO₂-C-H₂-O₂. J Metam Geol 8:89–124

  Google Scholar 

• Hsu LC (1968) Selected phase relationships in the system Al-Mn-Fe-Si-O-H: A model for garnet equilibria. J Petrol 9:40–83

  Google Scholar 

• Kennedy GC, Holser WT (1966) Pressure-volume-temperature and phase relations of water and carbon dioxide. Geol Soc America Mem 97:371–384

  Google Scholar 

• Kerrick DM (1968) Experiments on the upper stability limit of pyrophyllite at 1.8 kilobars and 3.9 kilobars water pressure. Am J Sci 266:204–214

  Article  Google Scholar 

• Kerrick DM (1972) Experimental determination of muscovite + quartz stability with P _H2O < P _total. Am J Sci 272:946–958

  Article  Google Scholar 

• Liou JG (1971) P-T stabilities of laumontite, wairakite, lawsonite and related minerals in the system CaAl₂Si₂O₈-SiO₂-H₂O. J Petrol 12:379–411

  Google Scholar 

• Massonne HJ, Schreyer W (1987) Phengite geobarometry based on the limiting assemblage with K-feldspar, phlogopite, and quartz. Contrib Mineral Petrol 96:212–224

  Article  Google Scholar 

• Massonne HJ, Schreyer W (1989) Stability field of the high-pressure assemblage talc + phengite and two new phengite barometers. Eur J Mineral 1:391–410

  Google Scholar 

• Mezger K, Rawnsley CM, Bohlen SR, Hanson GN (1990) U-Pb garnet, sphene, monazite, and rutile ages: Implications for the duration of high-grade metamorphism and cooling histories, Adirondack Mts., New York. J Geol 99:415–428

  Google Scholar 

• Miyashiro A (1973) Metamorphism and metamorphic belts. Allen & Unwin, London

  Google Scholar 

• Ohmoto H, Kerrick D (1977) Devolatilization equilibria in graphite systems. Am J Sci 277:1013–1044

  Article  Google Scholar 

• Okrusch M (1969) Die Gneishornfelse um Steinach in der Oberpfalz. Eine phasenpetrologische Analyse. Contrib Mineral Petrol 22:32–72

  Article  Google Scholar 

• Schreyer W (1988) Subduction of continental crust to mantle depths: Petrological evidence. Episodes 11:97–104

  Google Scholar 

• Spear FS (1988) The Gibbs method and Duhem’s theorem: The quantitative relationships among P,T, chemical potential, phase composition, and reaction progress in igneous and metamorphic systems. Contrib Mineral Petrol 99:249–256

  Google Scholar 

• Spear FS, Peacock SM, Kohn MJ, Florence FP, Menard T (1991) Computer programs for petrological P-T-t path calculations. Am Mineral 76:2009–2012

  Google Scholar 

• Storre B (1972) Dry melting of muscovite + quartz in the range P _s = 7 kb to P _s = 20 kb. Contrib Mineral Petrol 37:87–89

  Article  Google Scholar 

• Storre B, Karotke E (1972) Experimental data on melting reactions of muscovite + quartz in the system K₂O-Al₂O₃-SiO₂-H₂O to 20 Kb water pressure. Contrib Mineral Petrol 36:343–345

  Article  Google Scholar 

• Thompson AB (1970) A note on the kaolinite-pyrophyllite equilibrium. Am J Sci 268:454–458

  Article  Google Scholar 

• Thompson AB (1971) Analcite-albite equilibria at low temperatures. Am J Sci 271:79–92

  Article  Google Scholar 

• Winkler HGF (1979) Petrogenesis of metamorphic rocks, 5^th edn. Springer, Berlin Heidelberg New York

  Google Scholar 

• Zeh A, Holness M (2003) The effect of reaction overstep on garnet microstructures in metapelitic rocks of the Ilesha Schist Belt, SW Nigeria. J Petrol 44:967–994

  Article  Google Scholar 

• Zen E-An (1966) Construction of pressure-temperature diagrams for multicomponent systems after the method of Schreinemakers — A geometric approach. US Geol Survey Bull no 1225, 56 pp

  Google Scholar 

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