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Migmatite and melt segregation at Cooma, New South Wales

Published online by Cambridge University Press:  03 November 2011

D. J. Ellis  and
M. Obata
D. J. Ellis
Affiliation:
D. J. Ellis, Department of Geology, The Australian National University, GPO Box 4 Canberra City ACT 2601, Australia
M. Obata
Affiliation:
M. Obata, Department of Geology, Faculty of Science,Kumamoto University, Kumamoto 860, Japan
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Abstract

The Cooma Complex of southeastern New South Wales comprises an andalusite-bearing S-type granodiorite surrounded by migmatites and low-pressure metamorphosed pelitic and psammitic sediments. The migmatite formed by the melting reaction:

Biotite + Andalusite + K-feldspar + Quartz + V = Cordierite + Liquid

at about 350–400 MPa , 670-730°C.

The melanosome consists of biotite + cordierite + andalusite + K-feldspar + plagioclase + quartz + ilmenite, whereas the leucosome consists of cordierite + K-feldspar + quartz with extremely rare biotite and plagioclase. In a closed system, freezing of the leucosome melt patches should have resulted in cordierite back-reaction with melt to produce biotite and andalusite. The virtually anhydrous mineralogy of the leucosome patches, lack of cordierite reaction and the absence of biotite selvedges at the leucosome-melanosome contacts, indicates that the melt did not completely solidify in situ. These observations can be explained by an initial peritectic melting reaction in the migmatite being arrested from back-reaction upon cooling because of the removal of hydrous melt, enabling leucosome cordierite to escape back-reaction. We propose that the melanosome is the residue of partial melting but that the leucosome patches do not represent frozen melt segregations but rather the liquidus minerals (cumulates) which precipitated from the melt.

In the restite-rich granodiorite from the core of the Cooma Complex, cordierite of similar composition to that in the migmatite has reaction rims of biotite and andalusite and there are coexisting biotite and andalusite in the matrix. The granodiorite consisted of about 50 wt% melt together with resite biotite, quartz and plagioclase, which can possibly be identified in the surrounding migmatite. Previous work suggested that the Cooma Granodiorite can be derived from a mixture of the surrounding metasediments which are of similar composition in the high and low-grade areas surrounding the granodiorite. Re-examinatibn of those data shows that the high-grade metasediments are more An-rich than the low-grade rocks. The Cooma Granodiorite is very similar to the high-grade rocks in terms of Or-Ab-An ratio. This suggests derivation of the Cooma Granodiorite from the high-grade rocks and not from the relatively An-poor low-grade rocks which are typical of exposed sediments in the Lachlan Fold Belt. It is most likely that the granodiorite and envelope of high-grade rocks have been emplaced into the compositionally different lower grade rocks from slightly greater depths.

Keywords

cordieritegranodioriteleucosomeliquidus phase diagrammelanosomemigmatiterestite
Type
Research Article
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 83 , Issue 1-2: Second Hutton Symposium: The Origin of Granites and Related Rocks , 1992 , pp. 95 - 106
Copyright
Copyright © Royal Society of Edinburgh 1992

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References

Abbott, R. N. & Clarke, D. B. 1979. Hypothetical liquidus relationships in the subsystem Al2O3-FeO-MgO projected from quartz, alkali feldspar and plagioclase for a(H2O) ≤ 1. CAN MINERAL 17, 549–60.Google Scholar
Ashworth, J. R. 1985. Introduction. In Ashworth, J. R. (ed.) Migmatites, 135. Glasgow: Blackie.Google Scholar
Burnham, C. W. 1969. The importance of volatile consituents. In Yoder, H. S. (ed.) The evolution of the igneous rocks (Fiftieth anniversary perspectives), 439–82. Princeton: Princeton University Press.Google Scholar
Burnham, C. W. & Nekvasil, H. 1986. Equilibrium properties of granite pegmatite magmas. AMER MINERAL 71, 239–63.Google Scholar
Chappell, B. W. 1984. Source rocks of I- and S-type granites in the Lachlan Fold Belt, southeastern Australia. PHIL TRANS R SOC LONDON A310, 693707.Google Scholar
Chappell, B. W. & White, A. J. R. 1976. Plutonic rocks of the Lachlan Mobile Zone. 25th Int Geol Congr., Sydney, Excursion Guide No. 13C.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, 1111–38.Google Scholar
Ellis, D. J. 1986. Garnet-Liquid Fe-Mg equilibria and implications for the beginning of melting in the crust and subduction zones. AM J SCI 286, 765–91.Google Scholar
Flood, R. H. & Vernon, R. H. 1978. The Cooma Granodiorite, Australia: an example of in situ crustal anatexis? GEOLOGY 6, 8184.2.0.CO;2>CrossRefGoogle Scholar
Grant, J. A. 1985. Phase equilibria in partial melting of pelitic rocks. In Ashworth, J. R. (ed.) Migmatites, 86144. Glasgow: Blackie.CrossRefGoogle Scholar
Holdaway, M. J. 1971. Stability of andalusite and the aluminium-silicate phase diagram. AM J SCI 271, 97131.Google Scholar
Holdaway, M. J. & Lee, S. M. 1977. Fe-Mg cordierite stability in high grade pelitic rocks based on experimental, theoretical and natural observations. CONTRIB MINER PETROL 63, 175–98.Google Scholar
Hopwood, T. P. 1976. Stratigraphy and structural summary of the Cooma metamorphic complex. J GEOL SOC AUST 23, 345–60.CrossRefGoogle Scholar
Johannes, W. 1985. The significance of experimental studies for the formation of migmatites. In Ashworth, J. R. (ed.). Migmatites 3685. Glasgow: Blackie.Google Scholar
Joplin, G. A. 1942. Petrologic studies in the Ordovician of New South Wales I: The Cooma Complex. PROC LINN SOC NSW 67, 156–96.Google Scholar
Joplin, G. A. 1943. Petrologic studies in the Ordovician of New South Wales II: The northern extension of the Cooma Complex. PROC LINN SOC NSW 68, 159–83.Google Scholar
Joplin, G. A. 1962. An apparent magmatic cycle in the Tasman geosyncline. J GEOL SOC AUST 9, 5169.Google Scholar
Breton, N.Le & Thompson, A. B. 1988. Fluid-absent (dehydra- tion) melting of biotite in metapelites in the early stages of crustal anatexis. CONTRIB MINER PETROL 99, 226–37.Google Scholar
Menhert, K. R. 1968. Migmatites and the origin of granites. Amsterdam: Elsevier.Google Scholar
Munskgaard, N. C. 1988. Source of the Cooma Granodiorite, New South Wales—a possible role of fluid-rock interactions. AUST J EARTH SCI 35, 363–77.CrossRefGoogle Scholar
Nekvasil, H. 1988. Calculated effect of anorthite component on the crystallisation paths of H2O-undersaturated haplogranitic melts. AM MINERAL 73, 966–81.Google Scholar
Nekvasil, H. & Burnham, C. W. 1987. The individual effects of pressure and water content on phase equilibria in the “granite” system. In Magmatic Processes: Physicochemical principles. GEOCHEM SOC SPEC PUBL 1, 433–45.Google Scholar
Olsen, S. N. 1985. Mass balance in migmatites. In Ashworth, J. R. (ed.). Migmatites, pp. 145–79. Glasgow: Blackie.Google Scholar
Pidgeon, R. T. & Compston, W. 1965. The age and origin of the Cooma granite and its associated metamorphic zones, NSW J PETROL 6, 193222.Google Scholar
Richardson, S. W., Gilbert, M. C. & Bell, P. M. 1969. Experimental determination of kyanite-andalusite and andalusite-sillimanite equilibria: the aluminium silicate triple point. AM J SCI 267, 259–72.Google Scholar
Steele, D. A., Price, R. C., Fleming, P. D. & Gray, C. M. 1991. The origin of Cooma Supersuite granites: source protoliths and early magmatic processes. In Chappell, B. W. (Ed.) Second Hutton Symposium on granites and related rocks, Canberra 1991 (Abstracts). REC BMR GEOL GEOPHYS 1991/25, 100.Google Scholar
Thompson, A. B. 1976. Mineral reactions in pelitic rocks. II. Calculations of some P–T–X(Fe–Mg) phase relations. AM J SCI 276, 425–54.Google Scholar
Vallance, T. G. 1967. Palaeozoic low-pressure regional metamorphism in Australia. DANSK GEOL FOREN MEDD 17, 494503.Google Scholar
Vallance, T. G. 1969. Southern and Central Highlands fold belt: plutonic and metamorphic rocks. J GEOL SOC AUST 16, 180200.Google Scholar
Vernon, R. H. 1978. Pseudomorphous replacement of cordierite by symplectic intergrowths of andalusite, biotite and quartz. LITHOS 11, 283–9.CrossRefGoogle Scholar
Vielzeuf, D. & Holloway, J. R. 1988. Experimental determination of the fluid-absent melting relations in the pelitic system. CONTRIB MINER PETROL 98, 257276.Google Scholar
White, A. J. R. & Chappell, B. W. 1977. Ultrametamorphism and granitoid genesis. TECTONOPHYSICS 43, 722.CrossRefGoogle Scholar
White, A. J. R. & Chappell, B. W. 1988. Some supracrustal (S-type) granites of the Lachlan Fold Belt. TRANS R SOC EDINBURGH EARTH SCI 79, 169181.Google Scholar
White, A. J. R., Chappell, B. W. & Cleary, J. R. 1974. Geological setting and emplacement of some Australian Palaeozoic batholiths and implications for intrusive mechanisms. PAC GEOL 8, 159–71.Google Scholar
Wyborn, L. A. & 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.Google Scholar