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Some supracrustal (S-type) granites of the Lachlan Fold Belt

Published online by Cambridge University Press:  03 November 2011

A. J. R. White  and
B. W. Chappell
A. J. R. White
Affiliation:
Department of Geology, La Trobe University, Bundoora, Vic 3083, Australia.
B. W. Chappell
Affiliation:
Department of Geology, Australian National University, Canberra, ACT 2601, Australia.
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Abstract

S-type granites have properties that are a result of their derivation from sedimentary source rocks. Slightly more than half of the granites exposed in the Lachlan Fold Belt of southeastern Australia are of this type. These S-type rocks occur in all environments ranging from an association with migmatites and high grade regional metamorphic rocks, through an occurrence as large batholiths, to those occurring as related volcanic rocks. The association with high grade metamorphic rocks is uncommon. Most of the S-type granites were derived from deeper parts of the crust and emplaced at higher levels; hence their study provides insights into the nature of that deeper crust. Only source rocks that contain enough of the granite-forming elements (Si, Al, Na and K) to provide substantial quantities of melt can produce magmas and there is therefore a fertile window in the composition of these sedimentary rocks corresponding to feldspathic greywacke, from which granite magmas may be formed.

In this paper, three contrasting S-type granite suites of the Lachlan Fold Belt are discussed. Firstly, the Cooma Granodiorite occurs within a regional metamorphic complex and is associated with migmatites. It has isotopic and chemical features matching those of the widespread Ordovician sediments that occur in the fold belt. Secondly, the S-type granites of the Bullenbalong Suite are found as voluminous contact-aureole and subvolcanic granites, with volcanic equivalents. These granites are all cordierite-bearing and have low Na2O, CaO and Sr, high Ni, strongly negative εNd and high 87Sr/86Sr, all indicative of S-type character. However, the values of these parameters are not as extreme as for the Cooma Granodiorite. Evidence is discussed to show that these granites were derived from a less mature, unexposed, deeper and older sedimentary source. Other hypotheses such as basalt mixing are discussed and can be ruled out. The Strathbogie Suite granites are more felsic but all are cordierite-bearing and have chemical and other features indicative of an immature sedimentary source. They are closely associated with cordierite-bearing volcanic rocks. The more felsic nature of the suite results in part from crystal fractionation. It is suggested that the magma may have entered this “crystal fractionation” stage of evolution because it was a slightly higher temperature magma produced from an even less mature sediment than the Bullenbalong Suite. The production of these S-type magmas is discussed in terms of vapour-absent melting of metagreywackes involving both muscovite and biotite. The production of a magma in this way is consistent with the low H2O contents and geological setting of S-type granites and volcanic rocks in the Lachlan Fold Belt.

Keywords

fractionationgranitegreywackemagmameltperaluminousrestiteS-typeshalesource rocksupracrustal
Type
Research Article
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 79 , Issue 2-3: The Origin of Granites , 1988 , pp. 169 - 181
Copyright
Copyright © Royal Society of Edinburgh 1988

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References

Burnham, C. W. 1979. Magmas and hydrothermal fluids. In Barnes, H. L. (ed.) Geochemistry of Hydrothermal Ore Deposits (2nd ed), 71136. New York: Wiley.Google Scholar
Burnham, C. W. & Ohmoto, H. 1980. Late-stage processes of felsic magmatism. In Ishihara, S. & Takenouchi, S. (eds) Granite Magmatism and Related Mineralization. MINING GEOL SPECIAL ISSUE 8, 111.Google Scholar
Chappell, B. W. 1968. Volcanic greywackes from the Upper Devonian Baldwin Formation, Tamworth-Barraba District, New South Wales. J GEOL SOC AUST 15, 87102.CrossRefGoogle Scholar
Chappell, B. W. 1979. Granites as images of their source rocks. GEOL SOC AM PROG ABSTR 11, 400.Google Scholar
Chappell, B. W. 1984. Source rocks of I- and S-type granites in the Lachlan Fold Belt, southeastern Australia. PHILOS TRANS R SOC LONDON A310, 693707.Google Scholar
Chappell, B. W., White, A. J. R. & Wyborn, D. 1987. The importance of residual source material (restite) in granite petrogenesis. J PETROL 28, 11111138.CrossRefGoogle Scholar
Chappell, B. W., White, A. J. R. & Hine, R. 1988. Granite provinces and basement terranes in the Lachlan Fold Belt, southeastern Australia. AUST J EARTH SCI (in press).CrossRefGoogle Scholar
Chappell, B. W. & Stephens, W. E. 1988. Origin of infracrustal (I-type) granite magmas. TRANS R SOC EDINBURGH EARTH SCI 79, 7186.Google Scholar
Chappell, B. W. & White, A. J. R. 1974. Two contrasting granite types. PAC GEOL 8, 173174.Google Scholar
Chappell, B. W. & White, A. J. R. 1976. Plutonic rocks of the Lachlan Mobile Zone. International Geological Congress 25, Field Guide Excursion 13C.Google Scholar
Chappell, B. W. & White, A. J. R. 1984. I- and S-type granites in the Lachlan Fold Belt, southeastern Australia. In Keqin, Xu & Guangchi, Tu (eds) Geology of Granites and their Metallogenic Relations, 87101. Beijing: Science Press.Google Scholar
Clemens, J. D. & Vielzeuf, D. 1987. Constraints on melting and magma production in the crust. EARTH PLANET SCI LETT 86, 287306.CrossRefGoogle Scholar
Clemens, J. D. & Wall, V. J. 1981. Crystallization and origin of some peraluminous (S-type) granite magmas. CAN MINERAL 19, 111132.Google Scholar
Clemens, J. D. & Wall, V. J. 1984. Origin and evolution of a peraluminous silicic ignimbrite suite: the Violet Town Volcanics. CONTRIB MINERAL PETROL 88, 354371.CrossRefGoogle Scholar
Fleming, P. D. & White, A. J. R. 1984. Relationships between deformation and partial melting in the Palmer migmatites, South Australia. AUST J EARTH SCI 31, 351360.CrossRefGoogle Scholar
Gray, C. M. 1984. An isotopic mixing model for the origin of granitic rocks in southeastern Australia. EARTH PLANET SCI LETT 70, 4760.CrossRefGoogle Scholar
Hamilton, W. 1984. Review of Roddick, J. A. (ed.), Circum-Pacific Plutonic Terranes, Geological Society of America Memoir 159. EPISODES 7 (2), 48.Google Scholar
Hawkins, J. W. 1967. Prehnite-pumpellyite facies metamorphism of a graywacke shale series, Mount Olympus, Washington. AM J SCI 265, 798818.CrossRefGoogle Scholar
Hensel, H. D., McCulloch, M. T. & Chappell, B. W. 1985. The New England Batholith: constraints on its derivation from Nd and Sr isotopic studies of granitoids and country rocks. GEOCHIM COSMOCHIM ACTA 49, 369384.Google Scholar
Joplin, G. A. 1942. Petrological studies in the Ordovician of N.S.W. I. The Cooma Complex. PROC LINN SOC NSW 67, 156196.Google Scholar
McCarthy, T. S. & Hasty, R. A. 1976. Trace element distribution patterns and their relationship to the crystallization of granitic melts. GEOCHIM COSMOCHIM ACTA 40, 13511358.CrossRefGoogle Scholar
McCulloch, M. T. & Chappell, B. W. 1982. Nd isotopic characteristics of S- and I-type granites. EARTH PLANET SCI LETT 58, 5164.CrossRefGoogle Scholar
O'Neil, J. R. & Chappell, B. W. 1977. Oxygen and hydrogen isotope relations in the Berridale Batholith. J GEOL SOC LONDON 133, 559571.CrossRefGoogle Scholar
Pettijohn, F. J. 1957. Sedimentary Rocks, 2nd ed. New York: Harper Brothers.Google Scholar
Phillips, G. N., Wall, V. J. & Clemens, J. C. 1981. Petrology of the Strathbogie Batholith—a cordierite-bearing granite. CAN MINERAL 19, 4763.Google Scholar
Pidgeon, R. T. & Compston, W. 1965. The age and origin of the Cooma granite and its associated metamorphic zones, New South Wales. J PETROL 6, 193222.CrossRefGoogle Scholar
Pitcher, W. S. 1979. Comments on the geological environments of granites. In Atherton, M. P. & Tarney, J. (eds) Origin of granite batholiths, 18. Nantwich: Shiva.Google Scholar
Reed, J. J. 1957. Petrology of the lower Mesozoic rocks of the Wellington district. NZ GEOL SURV BULL NEW SER 57.Google Scholar
van der Molen, I. & Paterson, M. S. 1979. Experimental deformation of partially-melted granite. CONTRIB MINERAL PETROL 70, 299318.CrossRefGoogle Scholar
Wickham, S. M. 1987. The segregation and emplacement of granitic magmas. J GEOL SOC LONDON 144, 281297.CrossRefGoogle Scholar
White, A. J. R., Chappell, B. W. & Cleary, J. R. 1974. Geologic setting and emplacement of some Australian Paleozoic batholiths and implications for intrusive mechanisms. PAC GEOL 8, 159171.Google Scholar
White, A. J. R., Williams, I. S. & Chappell, B. W. 1976. The Jindabyne thrust and its tectonic, physiographic and petrogenetic significance. J GEOL SOC AUST 23, 105112.CrossRefGoogle Scholar
White, A. J. R. & Chappell, B. W. 1983. Granitoid types and their distribution in the Lachlan Fold Belt, southeastern Australia. In Roddick, J. A. (ed.) Circum-Pacific Plutonic Terranes, GEOL SOC AM MEM 159, 2134.Google Scholar
Wyborn, D., Chappell, B. W. & Johnston, R. M. 1981. Three S-type volcanic suites from the Lachlan Fold Belt, southeast Australia. J GEOPHYS RES 86, 1033510348.CrossRefGoogle Scholar
Wyborn, D. & Chappell, B. W. 1986. The petrogenetic significance of chemically related plutonic and volcanic rock units. GEOL MAG 123, 619628.CrossRefGoogle Scholar
Wyborn, L. A. I. & Chappell, B. W. 1983. Chemistry of the Ordovician and Silurian greywackes of the Snowy Mountains, southeastern Australia: an example of chemical evolution of sediments with time. CHEM GEOL 39, 8192.CrossRefGoogle Scholar
E-an, Zen 1986. Aluminum enrichment in silicate melts by fractional crystallization: some mineralogic and petrographic constraints. J PETROL 27, 10951117.Google Scholar