Prograde and retrograde P-T evolution of a Variscan high-temperature eclogite, French Massif Central, Haut-Allier

The P-T evolution of a mafic eclogite sample from the Haut-Allier was studied in order to constrain the dynamic of the Variscan subduction in the eastern French Massif Central. Three successive metamorphic stages M1, M2 and M3, are characterized by assemblages comprising garnet1-omphacite-kyanite, g...

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Bibliographic Details
Published in:Bulletin de la Société géologique de France 2020, Vol.191, p.14
Main Authors: de Hoym de Marien, Luc, Pitra, Pavel, Cagnard, Florence, Le Bayon, Benjamin
Format: Article
Language:English
Subjects:
Auvergne
Central Massif
Cooling
crystal fractionation
Earth Sciences
eclogite
Europe
France
french massif central
garnet group
geodynamics
granulites
Haut-Allier
Haute-Loire France
High temperature
hp granulite
igneous and metamorphic rocks
isobaric heating
La Borie France
mafic composition
metamorphic rocks
metamorphism
Mineralogy
nesosilicates
orogeny
orthosilicates
P-T conditions
partial melting
petrography
Petrology
plate tectonics
prograde metamorphism
p–t pseudosection
retrograde metamorphism
Sciences of the Universe
silicates
subduction
Tectonics
temperature
Variscan Orogeny
water
Western Europe
Zonation
Zoning
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Summary:The P-T evolution of a mafic eclogite sample from the Haut-Allier was studied in order to constrain the dynamic of the Variscan subduction in the eastern French Massif Central. Three successive metamorphic stages M1, M2 and M3, are characterized by assemblages comprising garnet1-omphacite-kyanite, garnet2-plagioclase, and amphibole-plagioclase, respectively, and define a clockwise P-T path. These events occurred at the conditions of eclogite (M1; ∼ 20 kbar, 650 °C to ∼ 22.5 kbar, 850 °C), high-pressure granulite (M2; 19.5 kbar and 875 °C) and high-temperature amphibolite facies (M3; < 9 kbar, 750-850 °C), respectively. Pseudosection modelling of garnet growth zoning and mineralogy of the inclusions reveal a prograde M1 stage, first dominated by burial and then by near isobaric heating. Subsequent garnet1 resorption, prior to a renewed growth of garnet2 is interpreted in terms of a decompression during M2. High-pressure partial melting is predicted for both the M1 temperature peak and M2. M3 testifies to further strong decompression associated with limited cooling. The preservation of garnet growth zoning indicates the short-lived character of the temperature increase, decompression and cooling cycle. We argue that such P-T evolution is compatible with the juxtaposition of the asthenosphere against the subducted crust prior to exhumation driven by slab rollback.
ISSN:0037-9409
1777-5817
1777-5817
DOI:10.1051/bsgf/2020016