Evidence of crustal disequilibrium melting, mingling processes, layering and deformation in UHT conditions: the marginal zone of the Egersund-Ogna massif-type anorthosite (S. Norway).

Duchesne, Jean-Clair; Grard, Aline

doi:10.1016/j.lithos.2021.106267

Article (Scientific journals)

Evidence of crustal disequilibrium melting, mingling processes, layering and deformation in UHT conditions: the marginal zone of the Egersund-Ogna massif-type anorthosite (S. Norway).

Duchesne, Jean-Clair; Grard, Aline

2021 • In Lithos, 398-399, p. 106267

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10.1016/j.lithos.2021.106267

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Keywords :

Rogaland anorthosite province; disequilibrium melting; mingling process; high-alumina basalt; UHT granulite facies

Abstract :

[en] Septa of banded gneisses crop out along the margin of the Proterozoic Sveconorwegian Egersund-Ogna (EGOG) anorthosite pluton. They permit to observe the effects of a diapiric intrusion of anorthosite on its envelope of gneisses. The rocks are mylonitic and result from a strong deformation in UHT granulite facies conditions due to contact metamorphism. Concordance of the foliations in the septa and in the leuconoritic margin of the anorthosite suggests that the deformation was linked to the ballooning of the anorthosite. The septa lithology is dominated by noritic gneisses interleaved with felsic gneisses and comprises minor amounts of mafic granofels, metaquartzites and metagrauwackes. A late charnockitic dyke is cutting across the foliated structure. Geochemical data (major and trace elements) indicate that the noritic gneisses did not result from the metamorphism of amphibolites belonging to the high-grade gneiss complex characteristic of the wall rocks of the Rogaland anorthosite province. Instead they have strong similarities with a high-alumina basalt that is the possible parental magma of the EGOG anorthosite. Slight variations from norite to leuconorite compositions were induced by metamorphic differentiation. The felsic rocks encompass a large interval of rock types from granite to tonalite and quartz diorite. They compare with leucogranitic enclaves occurring in the charnockitic upper part of the Bjerkreim-Sokndal layered intrusion. Most felsic lithologies show the signature (including high positive Eu anomalies) of anatectic processes in disequilibrium melting conditions and rapid extraction from the source rocks. Flowage differentiation in the emplacement process explains the various compositions, as commonly observed in migmatite leucosomes. The metaquartzites show a relatively high Ti concentration and the Ti-in-quartz geothermometer records a minimum temperature of 820°C. The study brings evidence that the high-alumina basalt and the felsic magmas were aggregated but did not interacted to yield hybrid magmas, possibly because the time interval was too short. They mingled in various proportions to form the norito-felsic gneisses. The aggregated magmas were intimately linked to the EGOG intrusion in which they played a role as a lubricating agent. They were injected into the wall rocks and were deformed by ballooning from superheated UHT conditions down to subsolidus conditions where mylonitic structures developed. Finally, a charnockitic magma was still able to intrude at a lower temperature below the ductile-brittle transition.

Disciplines :

Earth sciences & physical geography

Author, co-author :

Duchesne, Jean-Clair ; Université de Liège - ULiège > Département de Géologie

Grard, Aline ; Université de Liège - ULiège > Département de Biologie, Ecologie et Evolution > Aquapôle

Language :

English

Title :

Evidence of crustal disequilibrium melting, mingling processes, layering and deformation in UHT conditions: the marginal zone of the Egersund-Ogna massif-type anorthosite (S. Norway).

Publication date :

2021

Journal title :

Lithos

ISSN :

0024-4937

Publisher :

Elsevier, Netherlands

Volume :

398-399

Pages :

106267

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 09 June 2021

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Bibliography

Ardill, K.E., Paterson, S.R., Stanback, J., Alasino, P.H., King, J.J., Crosbie, S.E., Schlieren-bound magmatic structures record crystal flow-sorting in dynamic upper-crustal magma-mush chambers. Front. Earth Sci., 8, 2020, 190 (35 p).
Ashwal, L.D., The temporality of anorthosites. Can. Mineral. 48 (2010), 711–728.
Barbey, P., Layering and Schlieren in granitoids: a record of interactions between magma emplacement, crystallization and deformation in growing plutons. Geol. Belg. 12 (2009), 109–133.
Barbey, P., Bertrand, J.M., Angoua, S., Dautel, D., Petrology and U/Pb geochronology of the Telohat migmatites, Aleksod, Central Hoggar, Algeria. Contrib. Mineral. Petrol. 101 (1989), 207–219.
Becker, A., Holtz, F., Johannes, W., Liquidus temperatures and phase compositions in the system Qz-Ab-or at 5 kbar and very low water activities. Contrib. Mineral. Petrol. 130 (1998), 213–224.
Berg, J.H., Dry granulite mineral assemblages in the contact aureole of the Nain complex, Labrador. Contrib. Mineral. Petrol. 64 (1977), 32–52.
Blereau, E., Johnson, T., Clark, C., Taylor, R., Kinny, P., Hand, M., Reappraising the P-T evolution of the Rogaland-Vest Agder Sector, southwestern Norway. Geosci. Front. 8 (2017), 1–14.
Bolle, O., Duchesne, J.C., The apophysis of the Bjerkreim-Sokndal layered intrusion (Rogaland anorthosite province, SW Norway): a composite pluton build up by tectonically-driven emplacement of magmas along the margin of an AMC igneous complex. Lithos 98 (2007), 292–312.
Bolle, O., Diot, H., Liégeois, J.-P., Vander Auwera, J., The Farsund intrusion (SW Norway): a marker of late-Sveconorwegian (Grenvillian) tectonism along a newly defined major shear zone. J. Struct. Geol. 32 (2010), 1500–1518.
Boudreau, PELE- a version of the MELTS software program for the PC platform. Comput. Geosci. 25 (1999), 201–203.
Brown, C., Yakymchuk, C., Brown, M., Fanning, C., Korhonen, F., Piccoli, P., Siddoway, C., From source to sink: petrogenis of cretaceous anatectic granites from the Fosdick migmatite-granite complex, West Antarctica. J. Petrol. 57 (2016), 1241–1278.
Bybee, G.M., Ashwal, L.D., Shirey, S., Horan, M., Mock, T., Andersen, T., Pyroxene megacrysts in Proterozoic anorthosites: Implications for tectonic setting, magma source and magmatic processes at the Moho. Earth Planet. Sci. Lett. 389 (2014), 74–85.
Charlier, B., Duchesne, J.C., Vander Auwera, J., Storme, J.-Y., Maquil, R., Longhi, J., Polybaric fractional crystallization of high-alumina basalt parental magmas in the Egersund-Ogna massif-type anorthosite (Rogaland, SW Norway) constrained by plagioclase and high-alumina orthopyroxene megacrysts. J. Petrol. 51 (2010), 2547–2570.
Coint, N., Slagstad, T., Roberts, N.M.W., Marker, M., Røhr, T.S., Sørensen, B.E., The late Mesoproterozoic Sirdal Magmatic Belt, SW Norway: relationships between magmatism and metamorphism and implications for Sveconorwegian orogenesis. Precambrian Res. 265 (2015), 57–77.
Drüppel, K., Elsäber, L., Brandt, S., Gerdes, A., Sveconorwegian mid-crustal ultrahigh-temperature metamorphism in Rogaland, Norway: U-Pb LA-ICP-MS geochronology and pseudosections of sapphirine granulites and associated paragneisses. J. Petrol. 54 (2013), 305–350.
Duchesne, J.-C., The norito-granitic zone of Puntervoll-Lia (Rogaland anorthosite province, S. Norway): evolution of a genetic model. 2020, University of Liege (2268/249881).
Duchesne, J.-C., Hertogen, J., The Farsund Shear Zone: geochemical evidence for lithological diversity in the wall rock of the Rogaland anorthosite province, South Norway. Nor. J. Geol., 100, 2021, 202020, 10.17850/njg100–4–3.
Duchesne, J.-C., Liégeois, J.-P., The origin of nelsonite and high-Zr ferrodiorite associated with Proterozoic anorthosite. Ore Geol. Rev. 71 (2015), 40–56.
Duchesne, J.-C., Wilmart, E., Igneous charnockites and related rocks from the Bjerkreim-Sokndal layered intrusion (Southwest Norway): a jotunite (hypersthene monzodiorite)-derived A-type granitoid suite. J. Petrol. 38 (1997), 337–369.
Duchesne, J.-C., Demaiffe, D., Wilmart, E., Fidsel-Vardefjell-Itland: Apophysis, Hidra massif and enveloppe. Maijer, C., Padget, P., (eds.) The Geology of Southernmost Norway: An Excursion Guide Norges Geologiske Undersøkelse, Special Publication, vol. 1, 1987, 42–47.
Duchesne, J.-C., Liégeois, J.P., Vander Auwera, J., Longhi, J., The crustal tongue melting model and the origin of massive anorthosites. Terra Nova 11 (1999), 100–105.
Duchesne, J.-C., Shumlyanskyy, L., Mitrokhin, A.V., The jotunite of the Korosten AMCG complex (Ukrainian shield): Crust- or mantle-derived?. Precambrian Res. 299 (2017), 58–74.
Emslie, R.F., Anorthosite massifs, Rapakivi granites, and the late Proterozoic rifting of North America. Precambrian Res. 7 (1978), 61–98.
Emslie, R.F., Geology and petrology of the Harp Lake complex, Central Labrador: an example of Elsonian magmatism. Geol. Sur. Canada Bulletin 293 (1980), 1–136.
Emslie, R.F., Hamilton, M.A., Thiérault, R.J., Petrogenesis of a Mid-Proterozoic Anorthosite - Mangerite - Charnockite - Granite (AMCG) complex: isotopic and chemical evidence from the Nain plutonic suite. J. Geol. 102 (1994), 539–558.
Eskola, P., The mineral facies of rocks. Nor. Geol. Tidsskr. 6 (1920), 143–194.
Falkum, T., Geologisk kart over Norge, berggrunnskart Mandal, 1:250000. 1982 (Norges Geologiske Undersøkelse).
Fram, M.S., Longhi, J., Phase equilibria of dikes associated with Proterozoic anorthosite complexes. Am. Mineral. 77 (1992), 605–616.
Frost, B.R., Barnes, C.G., Collins, W.J., Arculus, R.J., Ellis, D.J., Frost, C.D., A geochemical classification for granitic rocks. J. Petrol. 42 (2001), 2033–2048.
Goldsmith, R., Granofels, a new metamorphic rock name. Journal of Geology, 67, 1959.
Granseth, A., Slagstad, T., Coint, N., Roberts, N.M.W., Røhr, T.S., Sørensen, B.E., Tectonomagmatic evolution of the Sveconorwegian orogen recorded in the chemical and isotopic compositions of 1070–920 Ma granitoids. Precambrian Res., 340, 2020, 105527.
Harrison, T.M., Watson, E.B., The behavior of apatite during crustal anatexis: equilibrium and kinetic considerations. Geochim. Cosmochim. Acta 48 (1984), 1467–1477.
Hegner, E., Emslie, R., Iaccheri, L., Hamilton, M.A., Sources of the Mealy Mountains and Atikonak River anorthosite-granitoid complexes, Grenville Province, Canada. Can. Mineral. 48 (2010), 787–808.
Hermans, G.A.E.M., Tobi, A.C., Poorter, R.P.E., Maijer, C., The high-grade metamorphic Precambrian of the Sirdal-Ørsdal area. Rogaland/Vest-Agder, south-west Norway. Norges Geologiske Undersøkelse 318 (1975), 51–74.
Kawamoto, T., Experimental constraints on differenciation and H2O abundance in calc-alkaline magmas. Earh Planetary Sci. Letters 144 (1996), 577–589.
Laurent, A.T., Duchene, S., Bingen, B., Bosse, V., Seydoux-Guillaume, A.-M., Two successive phases of ultrahigh temperature metamorphism in Rogaland, S. Norway: Evidence from Y-in-monazite thermometry. J. Metamorph. Geol. 36 (2018), 1009–1037.
Le Maître, R.W., A Classification of Igneous Rocks and Glossary of Terms. 1989, Blackwell Scientific Publications, Oxford.
Lehmann, J., Bybee, G.M., Hayes, B., Owen-Smith, T.M., Belyanin, G., Emplacement of the giant Kunene AMCG complex into a contractional ductile shear zone and implications for the Mesoproterozoic tectonic evolution of SW Angola. Int. J. Earth Sci., 2020, 10.1007/s00531-020-01837-5.
Longhi, J., Vander Auwera, J., Fram, M., Duchesne, J.C., Some phase equilibrium constraints on the origin of Proterozoic (Massif) anorthosites and related rocks. J. Petrol. 40 (1999), 339–362.
Marker, M., Schiellerup, H., Meyer, G.B., Robins, B., Bolle, O., Geological map of the Rogaland anorthosite Province (at scale 1:75,000). Duchesne, J.C., Korneliussen, A., (eds.) Ilmenite Deposits and their Geological Environments, 2003, Norges geologiske undersøkelse, Trondheim.
Michot, P., La série rubanée norito-granitique du massif anorthositique d'Egersund. Ann. Soc Géol. Belg. 62 (1939), 532–546.
Michot, P., La géologie de la catazone: le problème des anorthosites, la palingenèse basique et la tectonique catazonale dans le rogaland méridional (Norvège méridionale). Norges geologiske undersökelse. 212g, 1960, 1–54.
Mitchell, R.K., Indares, A., Ryan, B., High to ultrahigh temperature contact metamorphism and dry partial melting of the Tasiuyak paragneiss, Northern Labrador. J. Metamorph. Geol. 32 (2014), 535–555.
Morgan, J.W., Stein, H.J., Hannah, J.L., Markey, R.J., Wiszniewska, J., Re-Os study of ores from the Suwalki anorthosite massif, Northeast Poland. Mineral. Deposita 35 (2000), 391–401.
Neogi, S., Bolton, E.W., Chakraborty, S., Timescales of disequilibrium melting in the crust: constraints from modelling the distribution of multiple trace elements and a case study from the Lesser Himalayan rocks of Sikkim. Contrib. Mineral. Petrol., 168, 2014, 1020.
Nicoli, G., Stevens, G., Moyen, J.-F., Vezinet, A., Mayne, M., Insights into the complexity of crustal differentiation: K2O-poor leucosomes within metasedimentary migmatites from the Southern marginal Zone of the Limpopo Belt, South Africa. J. Metamorph. Geol. 35 (2017), 999–1022.
Patiño-Douce, A.E., Beard, J.S., Effects on P, f(O2) and Mg/Fe Ratio on dehydration melting of model metagreywackes. J. Petrol. 37 (1996), 999–1024.
Peccerillo, R., Taylor, S.R., Geochemistry of Eocene calc-alkaline volcanic rocks from the Kastamonu area, northern Turkey. Contrib. Mineral. Petrol. 58 (1976), 489–502.
Polat, A., Fryer, B.J., Appel, P.W.U., Kalvig, P., Kerrich, R., Dilek, Y., Yang, Z., Geochemistry of anorthositic differentiated sills in the Archean (~2970 Ma) Fiskenæsset complex, SW Greenland: Implications for parental magma compositions, geodynamic setting, and secular heat flow in arcs. Lithos 123 (2011), 50–72.
Prinzhoffer, A., Allègre, C., Residual peridotites and the mechanisms of partial melting. Earth Planet. Sci. Lett. 74 (1985), 251–265.
Roelandts, I., Duchesne, J.C., Rare-earth elements in apatite from layered norites and iron-titanium oxide ore-bodies related to anorthosites (Rogaland, S.W. Norway). Ahrens, L.H., (eds.) Origin and Distribution of the Elements, 1979, Pergamon, 199–212.
Ryan, B., Further results of mapping gneissic and plutonic rocks of the Nain area, Labrador. Current Res. Newfoundland Dept. Mines Energy, Geol. Surv. Branch 93-1 (1993), 61–75.
Ryan, B., The Nain-Churchill boundary and the Nain Plutonic Suite: a regional perspective on the geologic setting of the Voisey's Bay Ni-Cu-Co deposit. Econ. Geol. 95 (2000), 703–724.
Sawyer, E.W., Disequilibrium melting and the rate of melt-residuum separation during migmatization of mafic rocks from the Grenville Front, Quebec. J. Petrol. 32 (1991), 701–738.
Sawyer, E., Atlas of Migmatites. 2008, NRC Research Press, Ottawa, Ontario, Canada.
Schärer, U., Wilmart, E., Duchesne, J.C., The short duration and anorogenic character of anorthosite magmatism: U-Pb dating of the Rogaland complex, Norway. Earth Planet. Sci. Lett. 139 (1996), 335–350.
Schiellerup, H., Lambert, D.D., Prestvik, T., Robins, B., McBride, J.S., Larsen, R.B., Re-Os isotopic evidence for a lower crustal origin of massif-type anorthosites. Nature 405 (2000), 781–784.
Singh, J., Johannes, W., Dehydration melting of tonalites. 2. Compositions of melts and solids. Contrib. Mineral. Petrol. 125 (1996), 26–44.
Sisson, T., Ratajeski, K., Hankins, W., Glazner, A.F., Voluminous granitic magmas from common basaltic sources. Contrib. Mineral. Petrol. 148 (2005), 635–661.
Slagstad, T., Roberts, N.M.W., Coint, N., Høy, I., Sauer, S., Kirkland, C.L., Marker, M., Røhr, T.S., Henderson, I.H.C., Stormoen, M.A., Skår, Ø., Sørensen, B.E., Bybee, G.M., Magma-driven, high-grade metamorphism in the Sveconorwegian Province, Southwest Norway, during the terminal stages of Fennoscandian Shield evolution. Geosphere 14 (2018), 861–882.
Streckeisen, A., To each plutonic rock its proper name. Earth Sci. Rev. 12 (1976), 1–33.
Sun, S.S., McDonough, W.F., Chemical and isotopic systematices of oceanic basalts: Implications for mantle composition and processes. Saunders, A.D., Norry, M.J., (eds.) Magmatism in Ocean Basins, 1989, Geological Society of London Special Publication, 313–345.
Taylor, S., McLennan, S., The Continental Crust: Its Composition and Evolution. 1985, Blackwell, Oxford.
Taylor, J., Nicoli, G., Stevens, G., Frei, D., Moyen, J.-F., The processes that control leucosome compositions in metasedimentary granulites: Perspectives from the Southern marginal Zone migmatites, Limpopo Belt, South Africa. J. Metamorph. Geol. 32 (2014), 713–742.
Thomas, J.B., Watson, E.B., Spear, F.S., Shemmella, P.T., TitaniQ under pressure: the effect of pressure and temperature on the solubility of Ti in quartz. Contrib. Mineral. Petrol. 160 (2010), 743–759.
Vander Auwera, J., Diffusion controlled growth of pyroxene-bearing margins on amphibolite bands in the granulite facies of Rogaland (Southwestern Norway): implications for granulite formation. Contrib. Mineral. Petrol. 114 (1993), 203–220.
Vander Auwera, J., Longhi, J., Experimental study of a jotunite (hypersthene monzodiorite): constraints on the parent magma composition and crystallization conditions (P, T, fO2) of the Bjerkreim-Sokndal layered intrusion. Contrib. Mineral. Petrol. 118 (1994), 60–78.
Vander Auwera, J., Bologne, G., Roelandts, I., Duchesne, J.C., Inductively coupled plasma-mass spectrometry (ICP-MS) analysis of silicate rocks and minerals. Geol. Belg. 1 (1998), 49–53.
Vander Auwera, J., Bolle, O., Bingen, B., Liégeois, J.-P., Bogaerts, M., Duchesne, J.-C., De Waele, B., Longhi, J., Sveconorwegian massif-type anorthosites and related granitoids result from post-collisional melting of a continental arc root. Earth-Sci. Rev. 107 (2011), 375–397.
Vander Auwera, J., Bolle, O., Dupont, A., Pin, C., Paquette, J.-L., Charlier, B., Duchesne, J.-C., Mattielli, N., Bogaerts, M., Source-derived heterogeneities in the composite (charnockite-granite) ferroan Farsund intrusion (SW Norway). Precambrian Res. 251 (2014), 141–163.
Vander Auwera, J., Charlier, B., Duchesne, J.-C., Bingen, B., Longhi, J., Bolle, O., Comment on Bybee et al. (2014): Pyroxene megacrysts in Proterozoic anorthosites: Implications for tectonic setting, magma source and magmatic processes at the Moho. Earth Planet. Sci. Lett. 401 (2014), 378–380.
Watkins, J.M., Clemens, J., Treloar, P.J., Archaean TTGs as sources of younger granitic magmas: melting of sodic metatonalites at 0.6–1.2 GPa. Contrib. Mineral. Petrol. 154 (2007), 91–110.
Watson, E.B., Harrison, T.M., Zircon saturation revisited: temperature and compositional effects in a variety of crustal magma types. Earth Planet. Sci. Lett. 64 (1983), 295–304.
Wendlandt, R.F., Influence of CO2 on melting of model granulite facies assemblages: a model for the genesis of charnockites. Am. Mineral. 66 (1981), 1164–1174.
Wiebe, R.A., Smith, D., Sturm, M., King, E.M., Seckler, M.S., Enclaves in the Cadillac Mountain granite (coastal Maine): samples of hybrid magma from the base of the chamber. J. Petrol. 38 (1997), 293–423.
Wilmart, E., Duchesne, J.C., Geothermobarometry of igneous and metamorphic rocks around the Åna-Sira anorthosite massif: implications for the depth of emplacement of the South Norwegian anorthosites. Nor. Geol. Tidsskr. 67 (1987), 185–196.
Wilson, J.R., Robins, B., Nielsen, F., Duchesne, J.C., Vander Auwera, J., The Bjerkreim-Sokndal layered intrusion, Southwest Norway. Cawthorn, R.G., (eds.) Layered Intrusions, 1996, Elsevier, Amsterdam, 231–256.
Winchester, J.A., Floyd, P.A., Geochemical determination of different magma series and their differentiation products using immobile elements. Chem. Geol. 20 (1977), 325–343.