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Stability of F-Ti-phlogopite in the system phlogopite–sillimanite–quartz: an experimental study of dehydration melting in H2O-saturated and undersaturated conditions

Published online by Cambridge University Press:  05 July 2018

J. A. K. Tareen
Affiliation:
Department of Geology, University of Mysore, Manasagangotri, Mysore - 570 006, India
A. V. Keshava Prasad
Affiliation:
Department of Geology, University of Mysore, Manasagangotri, Mysore - 570 006, India
B. Basavalingu
Affiliation:
Department of Geology, University of Mysore, Manasagangotri, Mysore - 570 006, India
A. V. Ganesha
Affiliation:
Department of Geology, University of Mysore, Manasagangotri, Mysore - 570 006, India

Abstract

Melt generation during granulite-grade metamorphism is believed to be controlled by the stability temperatures of biotite, whose breakdown provides H2O and controls fluid-absent melting in the lower crust. In a simple KMASH system, the restite minerals crystallising due to incongruent melting of phlogopite depend upon the bulk composition. In an alumina-poor and silica-rich portion of the system (Phl + Qtz), enstatite appears with the melt, while in an alumina-rich system (Phl + Sil + Qtz) cordierite appears first instead of enstatite. Since the temperature of biotite stability is believed to be strongly controlled by its F and Ti content, it will have significant effect on the fluid-absent melting reactions during granulite-grade metamorphism of mica-containing granites as well as pelitic rocks in the deeper crust.

To understand such effects in an aluminous portion of the KMASH system, experiments were performed (between 850 and 1100°C and at 7, 10 and 12 kbar) with bulk composition containing 2Phl-6Sil- 9Qtz, where natural phlogopite with F/(F+OH) = 0.39 and Mg/(Mg+Fe) = 0.96 was used. In runs with this charge and containing 5 wt.% of excess water, cordierite appeared around 920°C at 7 kbar and 990°C at 12 kbar, and it disappeared at about 1080°C with the appearance of 221 sapphirine. In fluid-absent runs, these boundaries marginally shift to higher temperatures (30-50°C). The enstatite which was distinctly absent in H2O-saturated runs, crystallises in the high-temperature sapphirine field with up to 12 wt.% Al2O3 in H2O-undersaturated runs. The enstatite formation with cordierite is perhaps inhibited due to the Al consumption by cordierite and instability of Al-free enstatite at temperatures of cordierite stability. Re-equilibrated phlogopite persists in both the cordierite and sapphirine fields. The temperatures of the beginning of phlogopite breakdown are about 100-140°C above those reported for reaction Phl + Qtz → En + Sa + L (Vielzeuf and Clemens, 1992) with F and Ti-free phlogopite, but are ≈50–100°C lower than the temperatures reported (Tareen et al., 1995; Dooley and Patino Douce, 1996) for the same reaction containing F- and Ti- bearing phlogopite. The combined effect of the F and Ti content in phlogopite on its stability temperatures in the KMASH system has been found to be additive in relation to those containing only F or Ti. H2O-saturated runs produced per-aluminous melts with ≈27 wt.% Al2O3 in the cordierite field and ≈23% Al2O3 in the sapphirine field. The H2O-undersaturated runs produced melts rich in K2O (≈10 wt.%), SiO2 (72.5 wt.%) and relatively poor Al2O3 (12 wt.%).

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1998

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References

Bertrand, P., Ellis, D.J. and Green, D.H. (1991) The stability of sapphirine-quartz and hypersthenesillimanite- quartz assemblages: an experimental investigation in the system FeO-MgO-Al2O3-SiO2 under H2O and CO2 conditions. Contrib. Mineral. Petrol. 108, 5571.CrossRefGoogle Scholar
Bohlen, S.R., Boettcher, A.L., Wall, V.J., and Clemens, J.D. (1983) Stablity of phlogopite-quartz and sanidine-quartz: A model for melting in the lower crust. Contrib. Mineral. Petrol. 83, 270–7.CrossRefGoogle Scholar
Carrington, D.P. and Harley, S.L. (1995) The stability of osumilite in metapelitic granulites. J. Metam. Geol. 13, 613–25.CrossRefGoogle Scholar
Chatterjee, N.D. and Schreyer, W. (1972) The reaction enstatite+sillimanite=sapphirine+quartz in the system MgO-Al2O3-SiO2 . Contrib. Mineral. Petrol., 36, 4962.CrossRefGoogle Scholar
Dooley, D.F. and Patino Douce, A.E. (1996) Fluid-absent melting of F-rich phlogopite + rutile + quartz. Amer. Mineral., 81, 202–12.CrossRefGoogle Scholar
Hoffer, E. (1976) The reaction sillimanite + biotite + quartz = cordierite + K-feldspar H2O and partial melting in the system K2O-FeO-MgO-Al2O3-SiO2-H2O. Contrib. Mineral. Petrol., 55, 127–30.CrossRefGoogle Scholar
Holdaway, M.J. and Lee, S.M. (1977) Fe-Mg cordierite stability in high grade pelitic rocks based on experimental, theoretical and natural observations. Contrib. Mineral. Petrol., 63, 175–98.CrossRefGoogle Scholar
Montana, A. and Brearley, M. (1989) An appraisal of the stability of phlogopite in the crust and in the mantle. Amer. Mineral., 74, 14.Google Scholar
Motoyoshi, Y., Hensen, B.J. and Arima, M. (1993) Experimetnal study of high pressure stability limit of osumilite in the system K2O-MgO-Al2O3-SiO2: Implications for high temperature granulites. Eur. J. Mineral., 5, 439–40.CrossRefGoogle Scholar
Munoz, J.L. and Ludington, S.D. (1974) Fluorinehydroxyl exchange in biotite. Amer. J. Sci., 274, 396413.CrossRefGoogle Scholar
Newton, R.C. (1972) An experimental determination of the high pressure stability limits of magnesian cordierite under wet and dry conditions. J. Geol., 80., 398420.CrossRefGoogle Scholar
Patino Douce, A.E. (1993) Titanium substitution in biotite: An empirical model with applications to thermometry, O2 and H2O barometries and consequences for biotite stability. Chem. Geol., 108, 133–62.CrossRefGoogle Scholar
Patino Douce, A.E. and Johnston, D.A. (1991) Phase equilibria and melting productivity in the pelitic system: Implications for the origin of peraluminous granitoids and aluminous granulites. Contrib. Mineral. Petrol. 107, 202–18.CrossRefGoogle Scholar
Peterson, J.W., Chacko, T. and Keuhner, S.M. (1991) The effects of fluorine on the vapour absent melting of phlogopite and quartz: Implications for deep crustal processes. Amer. Mineral., 76, 470–6.Google Scholar
Peterson, J.W. and Newton, R.C. (1989) Reversed experiments on biotite-quartz-feldspar melting in the system KMASH. Implication for crustal anatexis. J. Geol., 97, 465–85.CrossRefGoogle Scholar
Skjerlie, K.P. and Johnston, A.D. (1993) Fluid absent melting behaviour of a fluorine rich tonalitic gneiss at mid-crustal pressures: Implication for the generation of anorogenic granites. J. Petrol., 34, 785815.CrossRefGoogle Scholar
Steven, G., Clemens, J.D. and Droop, G.T.R. (1997) Melt production during granulite-facies anatexis: experimental data from “primitive metasedimentary protoliths”. Contrib. Mineral. Petrol., (in press)CrossRefGoogle Scholar
Tareen, J.A.K., Keshava Prasad, A.V., Basavalingu, B. and Ganesha, A.V. (1995) The effect of fluorine and titanium on vapour-absent melting of phlogopite and quartz. Mineral. Mag., 59, 566–70.CrossRefGoogle Scholar
Tareen, J.A.K., Ganesha, A.V., Basavalingu, B. and Keshava Prasad, A.V. (1997) An experimental study of the breakdown reactions of the assemblage 2Phl- 6Sil-9Qtz in the system K2O-MgO-Al2O3-SiO2-H2O. Proceedings, Indian Acad. Sciences (Earth and Planetary Sciences. in press).Google Scholar
Tronnes, R.G., Edgar, A.D. and Arima, M. (1985) A high pressure–high temperature study of TiO2 solubility in Mg-rich phlogopite: Implication to phlogopite chemistry. Geochim. Cosmochim. Acta. 49, 2323–29.CrossRefGoogle Scholar
Valley, J.W., Petersen, E.U., Essene, E.J. and Bowman, J.R. (1992) Fluorphlogopite and fluortremolite in Adirondock marbles and calculated C-O-H-F fluid compositions. Amer. Mineral., 67, 545–57.Google Scholar
Vielzeuf, D. and Clemens, J.D. (1992) Fluid absent melting of phlogopite+quartz: Experiments and models. Amer. Mineral., 77, 1206–22.Google Scholar
Vielzeuf, D. and Holloway, J.R. (1988) Experimental determination of fluid absent melting relations in the pelitic system: consequences for crustal differentiation. Contrib. Mineral. Petrol., 98, 257–76.CrossRefGoogle Scholar