Petrology of an intrusion-related high-grade migmatite: implications for partial melting of metasedimentary rocks and leucosome-forming processes

Intrusion‐related migmatites comprise a substantial part of the high‐grade part of the southern Damara orogen, Namibia which is dominated by Al‐rich metasedimentary rocks and various granites. Migmatites consist of melanosomes with biotite+sillimanite+garnet+cordierite+hercynite and leucosomes are g...

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Published inJournal of metamorphic geology Vol. 16; no. 3; pp. 425 - 445
Main Authors JUNG, S., MEZGER, K., MASBERG, P., HOFFER, E., HOERNES, S.
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Science Ltd 01.05.1998
Subjects
anatexis
migmatite
Namibia
Nd and Sr isotopes
oxygen isotopes
trace elements
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Abstract Intrusion‐related migmatites comprise a substantial part of the high‐grade part of the southern Damara orogen, Namibia which is dominated by Al‐rich metasedimentary rocks and various granites. Migmatites consist of melanosomes with biotite+sillimanite+garnet+cordierite+hercynite and leucosomes are garnet‐ and cordierite‐bearing. Metamorphic grade throughout the area is in the upper amphibolite to lower granulite facies (5–6 kbar at 730–750 °C). Field evidence, petrographic observations, chemical data and mass balance calculations suggest that intrusion of granitic magmas and concomitant partial melting of metasedimentary units were the main processes for the generation of the migmatites. The intruding melts were significantly modified by magma mixing with in situ partial melts, accumulation of mainly feldspar and contamination with garnet from the wall rocks. However, it is suggested that these melts originally represented disequilibrium melts from a metasedimentary protolith. The occurrence of LILE‐, HFSE‐ and LREE‐enriched and ‐depleted residues within the leucosomes implies that both quartzo‐feldspathic and pelitic rocks were subjected to partial melting. Isotope ratios of the leucosomes are rather constant (143Nd/144Nd (500 Ma): 0.511718–0.511754, ε Nd (500 Ma): −3.54 to −5.11) and Sr (87Sr/86Sr (500 Ma): 0.714119–0.714686), the metasedimentary units have rather constant Nd isotope ratios (143Nd/144Nd (500 Ma): 0.511622–0.511789, ε Nd (500 Ma): −3.70 to −6.93) but variable Sr isotope ratios Sr (87Sr/86Sr (500 Ma): 0.713527–0.722268). The most restitic melanosome MEL 4 has a Sr isotopic composition of 87Sr/86Sr (500 Ma): 0.729380. Oxygen isotopes do not mirror the proposed contamination process, due to the equally high δ18O contents of metasediments and crustal melts. However, the most LILE‐depleted residue MEL 4 shows the lowest δ18O value (<10). Mass balance calculations suggest high degrees of partial melting (20–40%). It is concluded that partial melting was promoted by heat transfer and release of a fluid phase from the intruding granites. High degrees of partial melting can be reached as long as the available H2O, derived from the crystallization of the intruding granites, is efficiently recycled within the rock volume. Due to the limited amounts of in situ melting, it seems likely that such regional migmatite terranes are not the sources for large intrusive granite bodies. The high geothermal gradient inferred from the metamorphic conditions was probably caused by exhumation of deep crustal rocks and contemporaneous intrusion of huge masses of granitoid magmas. The Davetsaub area represents an example of migmatites formed at moderate pressures and high temperatures, and illustrates some of the reactions that may modify leucosome compositions. The area provides constraints on melting processes operating in high‐grade metasedimentary rocks.
AbstractList Intrusion‐related migmatites comprise a substantial part of the high‐grade part of the southern Damara orogen, Namibia which is dominated by Al‐rich metasedimentary rocks and various granites. Migmatites consist of melanosomes with biotite+sillimanite+garnet+cordierite+hercynite and leucosomes are garnet‐ and cordierite‐bearing. Metamorphic grade throughout the area is in the upper amphibolite to lower granulite facies (5–6 kbar at 730–750 °C). Field evidence, petrographic observations, chemical data and mass balance calculations suggest that intrusion of granitic magmas and concomitant partial melting of metasedimentary units were the main processes for the generation of the migmatites. The intruding melts were significantly modified by magma mixing with in situ partial melts, accumulation of mainly feldspar and contamination with garnet from the wall rocks. However, it is suggested that these melts originally represented disequilibrium melts from a metasedimentary protolith. The occurrence of LILE‐, HFSE‐ and LREE‐enriched and ‐depleted residues within the leucosomes implies that both quartzo‐feldspathic and pelitic rocks were subjected to partial melting. Isotope ratios of the leucosomes are rather constant ( 143 Nd/ 144 Nd (500 Ma): 0.511718–0.511754, ε Nd (500 Ma): −3.54 to −5.11) and Sr ( 87 Sr/ 86 Sr (500 Ma): 0.714119–0.714686), the metasedimentary units have rather constant Nd isotope ratios ( 143 Nd/ 144 Nd (500 Ma): 0.511622–0.511789, ε Nd (500 Ma): −3.70 to −6.93) but variable Sr isotope ratios Sr ( 87 Sr/ 86 Sr (500 Ma): 0.713527–0.722268). The most restitic melanosome MEL 4 has a Sr isotopic composition of 87 Sr/ 86 Sr (500 Ma): 0.729380. Oxygen isotopes do not mirror the proposed contamination process, due to the equally high δ 18 O contents of metasediments and crustal melts. However, the most LILE‐depleted residue MEL 4 shows the lowest δ 18 O value (<10). Mass balance calculations suggest high degrees of partial melting (20–40%). It is concluded that partial melting was promoted by heat transfer and release of a fluid phase from the intruding granites. High degrees of partial melting can be reached as long as the available H 2 O, derived from the crystallization of the intruding granites, is efficiently recycled within the rock volume. Due to the limited amounts of in situ melting, it seems likely that such regional migmatite terranes are not the sources for large intrusive granite bodies. The high geothermal gradient inferred from the metamorphic conditions was probably caused by exhumation of deep crustal rocks and contemporaneous intrusion of huge masses of granitoid magmas. The Davetsaub area represents an example of migmatites formed at moderate pressures and high temperatures, and illustrates some of the reactions that may modify leucosome compositions. The area provides constraints on melting processes operating in high‐grade metasedimentary rocks.
Intrusion‐related migmatites comprise a substantial part of the high‐grade part of the southern Damara orogen, Namibia which is dominated by Al‐rich metasedimentary rocks and various granites. Migmatites consist of melanosomes with biotite+sillimanite+garnet+cordierite+hercynite and leucosomes are garnet‐ and cordierite‐bearing. Metamorphic grade throughout the area is in the upper amphibolite to lower granulite facies (5–6 kbar at 730–750 °C). Field evidence, petrographic observations, chemical data and mass balance calculations suggest that intrusion of granitic magmas and concomitant partial melting of metasedimentary units were the main processes for the generation of the migmatites. The intruding melts were significantly modified by magma mixing with in situ partial melts, accumulation of mainly feldspar and contamination with garnet from the wall rocks. However, it is suggested that these melts originally represented disequilibrium melts from a metasedimentary protolith. The occurrence of LILE‐, HFSE‐ and LREE‐enriched and ‐depleted residues within the leucosomes implies that both quartzo‐feldspathic and pelitic rocks were subjected to partial melting. Isotope ratios of the leucosomes are rather constant (143Nd/144Nd (500 Ma): 0.511718–0.511754, ε Nd (500 Ma): −3.54 to −5.11) and Sr (87Sr/86Sr (500 Ma): 0.714119–0.714686), the metasedimentary units have rather constant Nd isotope ratios (143Nd/144Nd (500 Ma): 0.511622–0.511789, ε Nd (500 Ma): −3.70 to −6.93) but variable Sr isotope ratios Sr (87Sr/86Sr (500 Ma): 0.713527–0.722268). The most restitic melanosome MEL 4 has a Sr isotopic composition of 87Sr/86Sr (500 Ma): 0.729380. Oxygen isotopes do not mirror the proposed contamination process, due to the equally high δ18O contents of metasediments and crustal melts. However, the most LILE‐depleted residue MEL 4 shows the lowest δ18O value (<10). Mass balance calculations suggest high degrees of partial melting (20–40%). It is concluded that partial melting was promoted by heat transfer and release of a fluid phase from the intruding granites. High degrees of partial melting can be reached as long as the available H2O, derived from the crystallization of the intruding granites, is efficiently recycled within the rock volume. Due to the limited amounts of in situ melting, it seems likely that such regional migmatite terranes are not the sources for large intrusive granite bodies. The high geothermal gradient inferred from the metamorphic conditions was probably caused by exhumation of deep crustal rocks and contemporaneous intrusion of huge masses of granitoid magmas. The Davetsaub area represents an example of migmatites formed at moderate pressures and high temperatures, and illustrates some of the reactions that may modify leucosome compositions. The area provides constraints on melting processes operating in high‐grade metasedimentary rocks.
Author MEZGER, K.
HOFFER, E.
JUNG, S.
MASBERG, P.
HOERNES, S.
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  fullname: JUNG, S.
  organization: 1  Institut für Mineralogie, Kristallographie & Petrologie, Philipps-Universität Marburg, 35032 Marburg, Germany, 2  Max-Planck-Institut für Chemie, Abt. Geochemie, Postfach 3060, 55020 Mainz, Germany (email: sjung@geobar.mpch-mainz.mpg.de), 3 Mineralogisch-Petrologisches Institut der Universität Bonn, Poppelsdorfer Schloß, 53115 Bonn, Germany
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  surname: MEZGER
  fullname: MEZGER, K.
  organization: 1  Institut für Mineralogie, Kristallographie & Petrologie, Philipps-Universität Marburg, 35032 Marburg, Germany, 2  Max-Planck-Institut für Chemie, Abt. Geochemie, Postfach 3060, 55020 Mainz, Germany (email: sjung@geobar.mpch-mainz.mpg.de), 3 Mineralogisch-Petrologisches Institut der Universität Bonn, Poppelsdorfer Schloß, 53115 Bonn, Germany
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  fullname: MASBERG, P.
  organization: 1  Institut für Mineralogie, Kristallographie & Petrologie, Philipps-Universität Marburg, 35032 Marburg, Germany, 2  Max-Planck-Institut für Chemie, Abt. Geochemie, Postfach 3060, 55020 Mainz, Germany (email: sjung@geobar.mpch-mainz.mpg.de), 3 Mineralogisch-Petrologisches Institut der Universität Bonn, Poppelsdorfer Schloß, 53115 Bonn, Germany
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  surname: HOFFER
  fullname: HOFFER, E.
  organization: 1  Institut für Mineralogie, Kristallographie & Petrologie, Philipps-Universität Marburg, 35032 Marburg, Germany, 2  Max-Planck-Institut für Chemie, Abt. Geochemie, Postfach 3060, 55020 Mainz, Germany (email: sjung@geobar.mpch-mainz.mpg.de), 3 Mineralogisch-Petrologisches Institut der Universität Bonn, Poppelsdorfer Schloß, 53115 Bonn, Germany
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  organization: 1  Institut für Mineralogie, Kristallographie & Petrologie, Philipps-Universität Marburg, 35032 Marburg, Germany, 2  Max-Planck-Institut für Chemie, Abt. Geochemie, Postfach 3060, 55020 Mainz, Germany (email: sjung@geobar.mpch-mainz.mpg.de), 3 Mineralogisch-Petrologisches Institut der Universität Bonn, Poppelsdorfer Schloß, 53115 Bonn, Germany
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Weber C. & Barbey P.1986;The role of water, mixing processes and metamorphic fabric in the genesis of the Baume migmatites (Ardèche, France).Contributions to Mineralogy and Petrology, 92 481-491
Thompson A. B.1982;Dehydration melting of pelitic rocks and the generation of H2O-undersaturated granitic liquids.American Journal of Science, 282 1567-1595
Barbey P.Macaudiere J. & Nzenti J. P.1990;High-pressure dehydration melting of metapelites: evidence from the migmatites of Yaoundé (Cameroon).Journal of Petrology, 31 401-427
Tindle A. G. & Pearce J. A.1983;Assimilation and partial melting of continental crust: evidence from the mineralogy and geochemistry of autoliths and xenoliths.Lithos, 16 185-202
Thompson A. B. & England P. C.1984;Pressure-temperature-time path of regional metamorphism. 2. Some petrological constraints from mineral assemblages in metamorphic rock.Journal of Petrology, 25 929-955
England P. C. & Thompson A. B.1984;Pressure-temperature-time path of regional metamorphism. 1. Heat transfer during the evolution of regions of thickened continental crust.Journal of Petrology, 25 894-928
Kukla C.1993;Strontium isotope heterogeneities in amphibolite facies, banded metasediments - a case study from the late Proterozoic Kuiseb Formation of the Southern Damara orogen, Central Namibia.Memoirs of the Geological Survey, Namibia, 15
Prinzhofer A. & Allègre C. J.1985;Residual peridotites and the mechanisms of partial melting.Earth and Planetary Science Letters, 74 251-265
Kröner A.1982;Rb/Sr geochronology and tectonic evolution of the Pan-African Damara belt of Namibia, Southwestern Africa.American Journal of Science, 282 1471-1507
Chappel B. W. & White A. J. R.1977;Two contrasting granite types.Pacific Geology, 8 173-174
Miller C. F.1985;Are strongly peraluminous magmas derived from pelitic sedimentary sources?Journal of Geology, 93 673-689
Michard A.Guriet P.Soudant M. & Albarède F.1985;Nd isotopes in French Phanerozoic shales: External vs. internal aspects of crustal evolution.Geochimica et Cosmochimica Acta, 49 601-610
Vielzeuf D. & Holloway J. R.1988;Experimental determination of the fluid-absent melting relations in the pelitic system. Consequences for crustal differentiation.Contributions to Mineralogy and Petrology, 98 257-276
Ghent E. D.1976;Plagioclase-garnet-Al2SiO5-quartz: a potential geobarometer-geothermometer.American Mineralogist, 61 710-714
Sawyer E. W.1987;The role of partial melting and fractional crystallisation in determining discordant migmatite leucosome compositions.Journal of Petrology, 28 445-473
Currie K. L.1971;The reaction 3 cordierite=2 garnet+4 sillimanite+5 quartz as a geological thermometer in the Opinicon Lake region, Ontario.Contributions to Mineralogy, 33 215-226
Häussinger H.Okrusch M. & Scheepers D.1993;Geochemistry of premetamorphic hydrothermal alteration of metasedimentary rock associated with the Gorob massive sulfide prospect, Damara orogen, NamibiaEconomic Geology, 88 72-90
Millisenda C. C.Liew T. C.Hofmann A. W. & Köhler H.1994;Nd isotopic mapping of the Sri Lanka basement: update, and additional constraints from Sr isotopes.Precambrian Research, 66 95-110
Fyfe W. S.1973;The granulite facies, partial melting and the Archean crust.Philosophical Transactions Royal Society of London, A 273 457-461
Harris N. B. W. & Inger S.1992;Trace element modelling of pelite derived granites.Contributions to Mineralogyand Petrology, 110 46-56
Haack U.Hoefs J. & Gohn E.1982;Constraints on the origin of Damaran granites by Rb/Sr and δ18O data.Contributions to Mineralogy and Petrology, 79 279-289
Jacobsen S. B. & Wasserburg G. J.1980;Sm-Nd isotopic evolution of chondritesEarth and Planetary Science Letters, 50 139-155
Kleemann U. & Reinhardt J.1994;Garnet-biotite thermometry revisited: the effect of AlIV and Ti in biotite.European Journal of Mineralogy, 6 925-941
McDermott F. & Hawkesworth C. J.1990;Intracrustal recycling and upper-crustal evolution: A case study from the Pan-African Damara mobile belt, central Namibia.Chemical Geology, 83 263-280
Vielzeuf D. & Montel J.-M.1994;Partial melting of metagreywackes. Part 1. Fluid-absent experiments and phase relationshipsContributions to Mineralogy and Petrology, 117 375-393
Johannes W. & Gupta L. N.1982;Origin and evolution of a migmatiteContributions to Mineralogy and Petrology, 79 114-123
Holdaway M. J. & Lee S. M.1977;Fe-Mg cordierite stability in high grade pelitic rocks based on experimental, theoretical and natural observations.Contributions to Mineralogy and Petrology, 63 175-198
Kretz R.1983;Symbols for rock forming minerals.American Mineralogist, 68 277-279
Bea F.Pereira M. D. & Stroh A.1994;Mineral/leucosome trace-element partitioning in a peraluminous migmatite (a laser ablation-ICP-MS-study).Chemical Geology, 117 291-312
Whitney D. L. & Irving A. J.1994;Origin of K-poor leucosomes in a metasedimentary migmatite complex by ultrametamorphism, syn-metamorphic magmatism and subsolidus processes.Lithos, 32 173-192
Watt G. R. & Harley S. L.1993;Accessory phase controls on the geochemistry of crustal melts and restites produced during water-undersaturated partial melting.Contributions to Mineralogy and Petrology, 114 550-566
Harris N.1981;The application of spinel-bearing metapelites to P/T determinations: An example from South India.Contributions to Mineralogyand Petrology, 76 229-233
Sun S. S. & McDounough W. F.1989;Chemical and isotopic systematics of ocean basalts: implications for mantle composition and processes. In:Magmatism in the ocean basins, 42 313-345
Phillips G. N.Groves D. I. & Reed K.1989;Geochemistry of the Kuiseb metasediments around Windhoek, Namibia.Communications of the Geological Survey, Namibia, 5 19-30
Clayton R. N. & Mayeda T. D.1963;The use of bromine pentaflouride in the extraction of oxygen from oxides and silicates for isotope analysis.Geochimica et Cosmochimica Acta, 27 43-52
Hartmann O.Hoffer E. & Haack U.1983;Regional metamorphism in the Damara orogen: Interaction of crustal motion and heat transfer. In:Evolution of the Damara orogen, 11 233-241
Vielzeuf D.1983;The spinel and quartz associations in high grade xenoliths from Tallante (S.E. Spain) and their potential use in geothermometry and barometry.Contributions to Mineralogy and Petrology, 82 301-311
Finger F. & Clemens J. D.1995;Migmatization and 'secondary' granitic magmas: effect of emplacement and crystallization of 'primary' granitoids in Southern Bohemia, Austria.Contributions to Mineralogy and Petrology, 120 311-326
Kukla P. A.1992;Tectonics and sedimentation of a late Proterozoic Damaran convergent continental margin, Khomas Hochland, Central Namibia.Memoirs of the Geological Survey, Namibia, 12
Bühn B.Häussinger H.Kramm U.Kukla C.Kukla P. A. & Stanistreet I. G.1994;Tectonometamorphic patterns developed dur
1989; 42
1984; 25
1976; 61
1965; 50
1994; 66
1977; 63
1978; 1
1992; 55
1996; 37
1992; 12
1983; 16
1983; 11
1977
1976; 276
1987; 86
1989; 101
1990
1992; 110
1973; 273
1983; 64
1985
1994; 36
1985; 90
1983
1995; 122
1985; 93
1995; 120
1981; 76
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1992; 83
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1990; 31
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1963; 27
1990; 32
1986; 92
1994; 117
1987; 95
1993; 88
1995; 10
1981; 7
1988; 98
1988; 99
1977; 43
1991; 9
1991; 7
1985; 49
1982; 282
1990; 83
1993; 15
1971; 33
1980; 50
1988; 6
1980; 8
1983; 82
1985; 74
1993; 114
1990; 311
1971; 271
1987; 28
1977; 8
1994; 54
1994; 6
1976; 19
Phillips G. N. (e_1_2_1_54_2) 1989; 5
Bühn B. (e_1_2_1_8_2) 1994; 54
Nieberding F. (e_1_2_1_51_2) 1976; 19
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Jung S. (e_1_2_1_35_2) 1995; 10
Kukla C. (e_1_2_1_40_2) 1991; 7
Chappel B. W. (e_1_2_1_10_2) 1977; 8
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Kretz R. (e_1_2_1_37_2) 1983; 68
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Kukla P. A. (e_1_2_1_41_2) 1992; 12
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Sun S. S. (e_1_2_1_62_2) 1989; 42
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Sawyer E. W. (e_1_2_1_58_2) 1981; 7
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Wones D. R. (e_1_2_1_80_2) 1965; 50
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Miller R. McG. (e_1_2_1_47_2) 1983; 11
Miller R. McG. (e_1_2_1_48_2) 1983; 11
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Hartmann O. (e_1_2_1_26_2) 1983; 11
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Ghent E. D. (e_1_2_1_20_2) 1976; 61
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Snippet Intrusion‐related migmatites comprise a substantial part of the high‐grade part of the southern Damara orogen, Namibia which is dominated by Al‐rich...
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istex
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StartPage 425
SubjectTerms anatexis
migmatite
Namibia
Nd and Sr isotopes
oxygen isotopes
trace elements
Title Petrology of an intrusion-related high-grade migmatite: implications for partial melting of metasedimentary rocks and leucosome-forming processes
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