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Fluorine in igneous rocks and minerals with emphasis on ultrapotassic mafic and ultramafic magmas and their mantle source regions

Published online by Cambridge University Press:  05 July 2018

A. D. Edgar ,
L. A. Pizzolato  and
J. Sheen
A. D. Edgar
Affiliation:
Department of Earth Sciences, University of Western Ontario, London, Ontario, Canada N6A 5B7
L. A. Pizzolato
Affiliation:
Department of Earth Sciences, University of Western Ontario, London, Ontario, Canada N6A 5B7
J. Sheen
Affiliation:
Department of Earth Sciences, University of Western Ontario, London, Ontario, Canada N6A 5B7
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Abstract

In reviewing the distribution of fluorine in igneous rocks it is clear that F abundance is related to alkalinity and to some extent to volatile contents. Two important F-bearing series are recognized: (1) the alkali basalt—ultrapotassic rocks in which F increases with increasing K2O and decreasing SiO2 contents; and (2) the alkali basalt—phonolite—rhyolite series with F showing positive correlation with both total alkalis and SiO2. Detailed studies of series (1) show that F abundance in ultrapotassic magmas (lamproite, kamafugite, lamprophyre) occurs in descending order in the sequence phlogopite>apatite>amphibole>glass. Fluorine contents in the same minerals from fresh and altered mantle xenoliths may be several orders of magnitude less than those in the host kamafugite. For many lamproites, F contents correlate with higher mg# suggesting that F is highest in the more primitive magmas.

Experiments at mantle conditions (20 kbar, 900–1400°C) on simplified F-bearing mineral systems containing phlogopite, apatite, K-richterite, and melt show that F is generally a compatible element. Additionally, low F abundance in minerals from mantle xenoliths suggests that F may not be available in mantle source regions and hence is unlikely to partition into the melt phase on partial melting. Melting experiments on the compositions of F-free and F-bearing model phlogopite harzburgite indicate that even small variations in F content produce melts similar in composition to those of lamproite.

Keywords

fluorineigneous rocksmafic magmasultramafic magmas
Type
Halogen Mineralogy and Geochemistry
Information
Mineralogical Magazine , Volume 60 , Issue 399 , April 1996 , pp. 243 - 257
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1996

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References

Aoki, K. and Kanisawa, S. (1979) Ruorine contents of some hydrous minerals derived from upper mantle and lower crust. Lithos, 12, 167–71.CrossRefGoogle Scholar
Aoki, K., Ishiwaka, K. and Kanisawa, S. (1981) Fluorine geochemistry of basaltic rocks from continental and oceanic regions and their petrogenetic applications Contrib. Mineral. Petrol., 76, 55–9.CrossRefGoogle Scholar
Candela, P.A. (1986) Toward a thermodynamic model for the halogens in magmatic systems: applications to melt-vapor-apatite equilibria. Chem, Geol., 27, 289300.CrossRefGoogle Scholar
Dingwell, D.B. (1988) The structure and properties of fluorine-rich silicate melts: Implications for granite petrogenesis. In Recent Advances in the Geology of Granite-Related Mineral Deposits. Proc. Canad. Inst. Mining and Metallurgy Conference Montreal, 7286.Google Scholar
Edgar, A.D. (1987) Experimental petrology: inferences on the genesis of alkaline magmas with emphasis on their source regions. In The Alkaline Igneous Rocks Geol. Soc. Special Paper (Fitton, G. and Upton, B.G.J., eds.), 29—52.Google Scholar
Edgar, A.D. (1989) Barium- and strontium-enriched apatites in lamproites from West Kimberly, Western Australia. Amer. Mineral, 74, 889–95.Google Scholar
Edgar, A.D. (1992) Barium-rich phlogopite and biotite from some Quaternary alkaline mafic lavas from West Eifel, Germany. Europ. J. Mineral., 4, 321–30.CrossRefGoogle Scholar
Edgar, A.D. and Arima, M. (1985) Fluorine and chlorine contents of phlogopites crystallized from ultrapotassic rock compositions in high pressure experiments: Implications for halogen reservoirs in source rocks. Amer. Mineral., 70, 529–36.Google Scholar
Edgar, A.D. and Charbonneau, H.C. (1991) Fluorinebearing phases in lamproites. Mineral. Petrol., 44, 125–49.CrossRefGoogle Scholar
Edgar, A.D. and Pizzolato, L.A. (1995) Distribution of F in the model mantle systems K-richterite-apatite and phlogopite-K-richterite at 20 kbar: Consequences for F as a compatible element in ultrapotassic magma genesis. Contrib. Mineral. Petrol., 121, 247–57.CrossRefGoogle Scholar
Edgar, A.D. and Vukadinovic, D. (1992) Implications of experimental petrology to the evolution of ultrapotassic rocks. Lithos, 28, 187205.CrossRefGoogle Scholar
Edgar, A.D. and Vukadinovic, D. (1993) Potassium-rich clinopyroxenes in the mantle: An experimental investigation of a K-rich lamproite up to 60 kbar. Geochim. Cosmochim. Acta., 57, 5061–72CrossRefGoogle Scholar
Edgar, A.D., Charbonneau, H.E. and Mitchell, R.H. (1992) Phase relations in an armalcolite-phlogopite lamproite from Smoky Butte, Montana: Implications for lamproite genesis. J. Petrol., 33, 595–20.CrossRefGoogle Scholar
Edgar, A.D., Lloyd, F.E. and Vukadinovic, D. (1994a) The role of fluorine in the evolution of ultrapotassic magmas. Mineral. Petrol., 51, 173–93.CrossRefGoogle Scholar
Edgar, A.D., Mitchell, R.H. and Gulliver, C.E. (1994^) New mineral species found in experiments at continental mantle pressures (2—8 GPas) in kimberlite and lamproite compositions. International Symposium of the Physics and Chemistry of the Upper Mantle, Program with Abstracts Brazil, p 6.Google Scholar
Fitton, G. and Upton, B.G.J. (1987) The Alkaline Igneous Rocks. Geol. Soc. Spec. Paper, 30, 568pp.Google Scholar
Foley, S.F. (1988) The genesis of continental basic alkaline magmas: An interpretation in terms of redox melting. Special Lithosphere Issue, J. Petrol. (Menzies, M.A. and Cox, K.G., eds), 139—62.Google Scholar
Foley, S.E. (19B9a) Experimental constraints on phlogopite chemistry in lamproites. I. The effect of water activity and oxygen fugacity. Europ. J. Mineral., 1, 417–26.Google Scholar
Foley, S.F. (1989a) The genesis of lamproitic magmas in a reduced, fluorine-rich mantle. In Kimberlites and Related Rocks I: Their Composition, Occurrence, Origin and Emplacement. (Jacques, A.L., Ferguson, J., Green, D.H., O'ReiIIy, S.Y., Danchin, R.V., Janse, A.J.A., eds). Blackwell, Melbourne, 616—32.Google Scholar
Foley, S.F. (1990) Experimental constraints on phlogopite chemistry in lamproites. II. Effect of pressure- temperature variations. Europ. J. Mineral., 2, 327-41.Google Scholar
Foley, S.F. (1991) High pressure stability of the fluor- and hydroxy end members of pargasite and K-richterite. Geochim. Cosmochim. Acta., 55, 2689–91.CrossRefGoogle Scholar
Foley, S.F. (1992a) Petrological characterization of the source components of potassic magmas: Geochemical and experimental constraints. Lithos, 28, 187204.CrossRefGoogle Scholar
Foley, S.F. (1992b) Vein plus wall rock melting mechanisms in the lithosphere and the origin of potassic alkaline magmas. Lithos, 28, 435–54.CrossRefGoogle Scholar
Foley, S.F., Taylor, W.R. and Green, D.H. (1986a) The effect of fluorine on phase relationships in the system KAlSiO4-Mg2SiO4-SiO2 at 28 kbar and the solution mechanism of fluorine on silicate melts. Contrib, Mineral Petrol, 93, 4655.CrossRefGoogle Scholar
Foley, S.F., Taylor, W.R., and Green, D.H. (1986^) The role of fluorine and oxygen fugacity in the genesis of the ultrapotassic rocks. Contrib. Mineral. Petrol, 94, 383–92.Google Scholar
Foley, S.F., Venturelli, G., Green, D.H., and Toscani, L. (1987) The ultrapotassic rocks: Characteristics,classification, and constraints for petrogenetic models. Earth Sci. Rev., 24, 81—134.CrossRefGoogle Scholar
Jones, A.P., Smith, J.V. and Dawson, J.B. (1982) Mantle metasomatism of 14 veined peridotites from Bulfontein mine South Africa. J. Geol., 90, 435–53.CrossRefGoogle Scholar
Kuellner, F.J., Vispcky, A.P. and Tuttle, O.F. (1966) Preliminary survey of the system barite-calcite- fluorite at 500 bars. In Carbonatites (Tuttle, D.F. and Gittins, J., eds). Interscience, N.Y., 353—64.Google Scholar
Kushiro, I., Syono, Y. and Akimoto, S. (1967). Stability of phlogopite at high pressures and possible presence of phlogopite in the Earth's upper mantle. Earth Planet. Sci. Lettr., 3, 197203.CrossRefGoogle Scholar
Lloyd, F.E. (1987) Characterization of mantle metasomatic fluids in spinel lherzolites and alkali clinopyr- oxenites from the West Eifel and southwest Uganda. In Mantle Metasomatism (Menzies, M., Hawkesworth, C.J., eds.), Academic Press, London, 91124.Google Scholar
Lloyd, F.E. and Bailey, D.K. (1975) Light element metasomatism of the continental mantle: the evidence and the consequences. Phys. Chem. Earth, 9, 389416.CrossRefGoogle Scholar
Lloyd, F.E., Arima, M. and Edgar, A.D. (1985) Partial melting of a phlogopite clinopyroxenite from southwest Uganda: An experimental study bearing on the origin of highly potassic continental rift volcanism. Contrib. Mineral. Petrol., 91, 321–9.CrossRefGoogle Scholar
Mitchell, R.H. and Bergman, S.O. (1991). Petrology of Lamproites. Plenum, New York, 441pp.CrossRefGoogle Scholar
Modreski, P.J. and Boettcher, A.L. (1973) Phase relations in the system K2O—MgO-CaO-Al2O3- SiO2-H2O to 35 kbar, a better model for micas in the interior of the earth. Amer. J. Sci., 273, 385414.CrossRefGoogle Scholar
Nixon, P.H. (1987) Mantle Xenoliths. Wiley, Chichester, 844 pp.Google Scholar
Peterson, T.D., Esperanca, S. and Le Cheminant, A.M. (1994) Geochemistry and origin of the Proterozoic ultrapotassic rocks of the Churchill Province, Canada, Mineral Petrol., 51, 251–76.CrossRefGoogle Scholar
Schilling, J.G., Bergeron, M.B., and Evans, R. (1980) Halogens in the mantle beneath the North Atlantic. Phil. Trans. R. Soc. London A297, 147—78.Google Scholar
Smith, J.V., Delaney, J.S., Hervig, R.L. and Dawson, J.B. (1981) Storage of F and Cl in the upper mantle: Geochemical implications. Lithos, 14, 133–47.CrossRefGoogle Scholar
Sobelev, A., Sobelev, N., Smith, C.B. and Dubessy, J. (1989) Fluid and melt compositions in lamproites in kimberlites based on the study of inclusions in olivine. In Kimberlites and Related Rocks I: Their composition, occurrence, origin and emplacement.(Jacques, A.L., Ferguson, J., Green, D.H., O'Reilly, S.Y., Danchin, R.V., Janse, A.J.A., eds). Blackwell, Melbourne, 220—40.Google Scholar
Unni, C.K. and Schilling, J.G. (1978) Cl and Br degassing by volcanism along the Reykjanes ridge and Iceland. Nature, 272, 1923.CrossRefGoogle Scholar
Vukadinovic, D. and Edgar, A. D. (1993) Phase relations in the phlogopite-apatite system at 20 kbar: Implications for the role of fluorine in mantle melting. Contrib. Mineral. Petrol., 114, 247–54.CrossRefGoogle Scholar
Wagner, C. and Velde, D. (1986) The mineralogy of K- richterite bearing lamproites. Amer. Mineral, 71, 1737.Google Scholar
Wedepohl, K.H. (1978) Fluorine: Abundance in common igneous rocks. In Handbook of Geochemistry Elements Scet. 9E, 19.Google Scholar