Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-24T21:18:54.642Z Has data issue: false hasContentIssue false
  • English
  • Français

Pan-African charnockite formation in Kerala, South India

Published online by Cambridge University Press:  01 May 2009

A. K. Choudhary ,
N. B. W. Harris ,
P. van Calsteren  and
C. J. Hawkesworth
A. K. Choudhary
Affiliation:
Department of Earth Sciences, Open University, Milton Keynes MK7 6AA, U.K.
N. B. W. Harris
Affiliation:
Department of Earth Sciences, Open University, Milton Keynes MK7 6AA, U.K.
P. van Calsteren
Affiliation:
Department of Earth Sciences, Open University, Milton Keynes MK7 6AA, U.K.
C. J. Hawkesworth
Affiliation:
Department of Earth Sciences, Open University, Milton Keynes MK7 6AA, U.K.
Get access Rights & Permissions [Opens in a new window]

Abstract

Sm-Nd mineral ages of gneisses and associated granulites from the Ponmudi incipient charnockite locality (South India) indicate that granulite metamorphism occurred at, or shortly after, 558 Ma. Proterozoic ages recorded by garnet separates reflect a detrital age or an earlier metamorphic event preserved by inclusions within garnet. The age of post-metamorphic uplift (440–460 Ma) is constrained by Sr isotope equilibration between biotite and plagioclase. Since charnockite formation and subsequent uplift north of the Palghat-Cauvery shear zone had terminated by earliest Proterozoic time, these results confirm two distinct periods of granulite formation in South India and suggest that the Palghat-Cauvery shear zone represents the boundary between two blocks of strongly contrasting geological histories. Both incipient charnockite formation and subsequent uplift at Ponmudi may be correlated with the tectonothermal evolution of the Highlands Group in Sri Lanka. The similarity between Nd and Sr model ages for charnockites and gneisses from Ponmudi indicates that no significant Rb-Sr fractionation has occurred during the crustal history of these incipient charnockites. Pb isotopic ratios suggest that Th-U ratios were fractionated during charnockite formation at about 500 Ma. In contrast to charnockites found north of the Palghat-Cauvery shear zone, fractionation of U-Pb during the Archaean did not occur in the Ponmudi granulites.

Type
Articles
Information
Geological Magazine , Volume 129 , Issue 3 , May 1992 , pp. 257 - 264
Copyright
Copyright © Cambridge University Press 1992

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Baur, N., Kroner, A. & Todt, W. 1987. Prograde and retrograde metamorphic reactions in high-grade gneisses of Sri Lanka: structural control and U-Pb zircon data. Terra Cognita 7, 133–4.Google Scholar
Bernard-Griffiths, J., Jahn, B.-M. & Sen, S. K. 1987. Sm-Nd isotopes and REE geochemistry of Madras granulites: an introductory statement. Precambrian Research 37, 343–55.CrossRefGoogle Scholar
Buhl, D., Grauert, B. & Raith, M. 1983. U-Pb zircon dating of Archaean rocks from the South India craton: results from the amphibolite to granulite facies transition zone at Kabbal quarry, southern Karnataka, Fortschritte Mineralogie 61, 43–5.Google Scholar
Burton, K. W. & O'Nions, R. K. 1990. The timescale and mechanism of granulite formation at Kurunegala, Sri Lanka. Contributions to Mineralogy and Petrology 106, 6689.CrossRefGoogle Scholar
Cohen, A. S., O'Nions, R. K., Siegenthaler, R. & Griffin, W. L. 1988. Chronology of the pressure-temperature history recorded by a granulite terrain. Contributions to Mineralogy and Petrology 98, 303–11.CrossRefGoogle Scholar
Crawford, A. R. 1969. India, Ceylon and Pakistan: new age data and comparisons with Australia. Nature 223, 380–4.CrossRefGoogle Scholar
De Paolo, D. J. 1981. Nd isotopes in Colorado Front Range and crust–mantle evolution in the Proterozoic. Nature 291, 193–6.CrossRefGoogle Scholar
Dodson, M. H. 1979. The theory of cooling ages. In Lectures in Isotope Geology (eds Jager, E. and Hunziker, J. C.), pp. 194202. Heidelberg: Springer-Verlag.CrossRefGoogle Scholar
Drury, S. A. & Holt, R. W. 1980. The tectonic framework of the south Indian craton: a reconnaissance involving LANDSAT imagery. Tectonophysics 65, Tl–T15.CrossRefGoogle Scholar
Giletti, B. J. 1991. Rb and Sr diffusion in alkali feldspars, with implications for cooling histories of rocks. Geochimica et Cosmochimica Acta 55, 1331–43.CrossRefGoogle Scholar
Grauch, R. I. 1989. Rare earth elements in metamorphic rocks. In Geochemistry and Mineralogy of Rare Earth Elements (eds Lipin, B. R. and McKay, G. A.), pp. 147–68. Mineralogical Society of America, Reviews in Mineralogy Series Vol. 21.CrossRefGoogle Scholar
Grew, E. S. & Manton, W. J. 1984. Age of allanite from Kabbaldurga quarry, Karnataka. Journal of the Geological Society of India 25, 193–5.Google Scholar
Hansen, E. C., Hickman, M. H., Grant, N. K. & Newton, R. C. 1985. Pan-African age of ‘Peninsular Gneiss’ near Madurai, South India. EOS 66, 419–20.Google Scholar
Hansen, E. C., Janardhan, A. S., Newton, R. C., Prame, W. K. B. N. & Ravindra Kumar, G. R. 1987. Arrested charnockite formation in southern India and Sri Lanka. Contributions to Mineralogy and Petrology 96, 225–44.CrossRefGoogle Scholar
Harris, N. B. W. & Bickle, M. J. 1989. Advective fluid transport during charnockite formation; an example from southern India. Earth and Planetary Science Letters 93, 151–6.CrossRefGoogle Scholar
Harris, N. B. W. & Inger, S. In press. Trace element characteristics of pelite-derived granites. Contributions to Mineralogy and Petrology.Google Scholar
Jackson, D. H., Mattey, D. & Harris, N. B. W. 1988. Carbon isotope compositions of fluid inclusions in charnockites from southern India. Nature 333, 167–70.CrossRefGoogle Scholar
Keppler, H. & Wyllie, P. J. 1990. Role of fluids in transport of uranium and thorium in magmatic processes. Nature 348, 531–3.CrossRefGoogle Scholar
Kroner, A., Williams, I. S., Compston, W., Baur, N., Vitanage, P. W. & Perera, L. R. K. 1987. Zircon ion microprobe dating of high-grade rocks in Sri Lanka. Journal of Geology 95, 775–91.CrossRefGoogle Scholar
Milisenda, C. C., Liew, T. C., Hofmann, A. W. & Kroner, A. 1988. Isotopic mapping of age provinces in Precambrian high-grade terrains: Sri Lanka. Journal of Geology 96, 608–15.CrossRefGoogle Scholar
Peucat, J. J., Vidal, P., Bernard-Griffiths, J. & Condie, K. C. 1989. Sr, Nd and Pb isotopic systematics in the Archaean low-to high-grade transition zone of southern India; syn-accretion vs. post-accretion granulites. Journal of Geology 97, 537–50.CrossRefGoogle Scholar
Raith, M., Hoernes, S., Klatt, E. & Stahle, H. J. 1989. Contrasting mechanisms of charnockite formation in the amphibolite to granulite grade transition zones of southern India. In Fluid Movements–Element Transport and the Composition of the Deep Crust (ed. Bridgwater, D.), pp. 2938. NATO ASI Series 281. Plenum Press.CrossRefGoogle Scholar
Ravindra Kumar, G. P., Srikantappa, C. & Hansen, E. C. 1985. Charnockite in the making at Ponmudi, Kerala, South India. Nature 313, 207–9.CrossRefGoogle Scholar
Srikantappa, C., Raith, M. & Spiering, B. 1985. Progressive charnockitization of a leptynite-khondalite suite in southern Kerala, India—evidence for formation of charnockites through decrease in fluid pressure? Journal of tile Geological Society of India 26, 849–72.Google Scholar
Stacey, J. S. & Kramers, J. D. 1975. Approximation of terrestrial lead isotope evolution by a two-stage model. Earth and Planetary Science Letters 26, 207–21.CrossRefGoogle Scholar
Vance, D. & O'Noins, R. K. 1990. Isotopic chronometry of zoned garnets: growth kinetics and metamorphic histories. Earth and Planetary Science Letters 97, 227–40.CrossRefGoogle Scholar