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The retrogression of ultramafic granulites from the Scourian of NW Scotland

Published online by Cambridge University Press:  05 July 2018

Jane D. Sills
Jane D. Sills*
Affiliation:
Geology Department, University of Leicester, Leicester, LE1 7RH
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Abstract

Scourian ultramafic granulites from the Assynt region, of Sutherland were retrogressed to amphibolite facies during the Inverian and in Laxfordian shear zones. Inverian assemblages are dominantly chlorite and tremolite with minor anthophyllite and dolomite. Laxfordian assemblages are cummingtonite, chlorite, and dolomite with only minor amounts of tremolite. Retrogression took place on a falling temperature path with temperatures between 750 and 550°C, and with H2O forming more than 90% of the fluid phase. Initially retrogression was caused by the influx of large volumes of hydrous fluid associated with the development of Inverian folds. During the Laxfordian shearing PCO2 was increased slightly. Serpentinization of olivine occurred at a much later stage.

Type
Research Article
Information
Mineralogical Magazine , Volume 46 , Issue 338 , March 1982 , pp. 55 - 61
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1982

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References

Beach, A., and Fyfe, W. S. (1972 Contrib. Mineral. Petrol. 36, 175.CrossRefGoogle Scholar
Beach, A., and Fyfe, W. S. and Tarney, J. (1978 Precamb. Res. 7, 325.CrossRefGoogle Scholar
Bowes, D. R., Wright, A. E., and Park, R.G. (1964 J. Geol. Soc. Lond. 120, 153.CrossRefGoogle Scholar
Chapman, H. J., and Moorbath, S. (1977 Nature 268, 41.CrossRefGoogle Scholar
Day, H. W., and Halbach, H. (1979 Am. Mineral. 64, 809.Google Scholar
Evans, B. W., and Trommsdorff, V. (1974 Am. J. Sci. 274, 274.CrossRefGoogle Scholar
Fawcett, J. J., and Yoder, H. S. (1966 Am. Mineral. 51, 353.Google Scholar
Frost, R. B. (1975 J. Petrol. 16, 272.CrossRefGoogle Scholar
Greenwood, H. J. (1963. Ibid. 4, 317.Google Scholar
Greenwood, H. J. (1971 Am. J. Sci. 270, 151.CrossRefGoogle Scholar
Helgeson, H. C., Delaney, J. M., Nesbitt, H. W., and Bird, D. K. (1978 Ibid. 278-A, 1.Google Scholar
Johannes, W. (1969 Ibid. 267, 1083.Google Scholar
Powell, R. (1978 Equilibrium thermodynamics in Petrology (Harper and Row, London).Google Scholar
Rollinson, H. R. (1980 Mineral Mag. 43, 623.CrossRefGoogle Scholar
Savage, D., and Sills, J. D. (1980 Contrib. Mineral. Petrol. 74, 153.CrossRefGoogle Scholar
Sheraton, J. W., Tarney, J., Wheatley, T. J., and Wright, A. E. (1973 In Park, R. G., and Tarney, J. (eds). The Early Precambrian of Scotland and Related Rocks of Greenland. (Keele Univ. Press), 31.Google Scholar
Sills, J. D. (1981 unpubl. Ph.D. Thesis. Univ. of Leicester.Google Scholar
Tarney, J. (1973 In Park, R. G., and Tarney, J. (eds). The Early Precambrian of Scotland and Related Rocks of Greenland (Keele Univ. Press), 105.Google Scholar
Winkler, H. G. F. (1976 Petrogenesis of metamorphic rocks. 4th edition. (Springer-Verlag).CrossRefGoogle Scholar