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《International Geology Review》2012,54(6):633-641
To estimate the amount of H2O stored at lower crustal levels after burial, we considered the pile of migmatitic paragneisses in the Variscan Ulten Zone as a case study area. We constructed a pseudosection in the system K2O-Na2O-CaO-FeO-MnO-MgO-Al2O3-SiO2-TiO2-H2O for an average paragneiss, a relevant prograde PT path (8.5 kbar, 600°C; 11.5 kbar, 750°C; 14.0 kbar, 1000°C) and H2O contents between 0 and 10 wt.%. Based on an assemblage of garnet?+?biotite?+?white mica?+?kyanite?+?20–30 vol.% former melt (now represented mainly by leucosomes composed of plagioclase?+?quartz), a bulk H2O content of 3.2 ± 1.1 wt.% was estimated for a peak temperature ranging between 770 and 800°C. Before melting, somewhat less than 1.8 wt.% H2O was stored in minerals. Thus, a considerable amount of H2O must have either resided in pore spaces along grain boundaries or, much less likely, infiltrated the paragneisses from below. Evidently, significant quantities of H2O as a free phase may be stored in buried sialic crust, resulting in considerable melting of deep-seated rocks during continent–continent collision. 相似文献
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Giovanna T. Sapienza Marco Scambelluri Roberto Braga 《Contributions to Mineralogy and Petrology》2009,158(3):401-420
We document the presence of dolomite ± apatite in orogenic peridotites from the Ulten Zone (UZ, Italian Alps), the remnants
of a Variscan mantle wedge tectonically coupled with eclogitized continental crust. These dolomite peridotites are associated
with dominant carbonate-free amphibole peridotites, which formed in response to infiltration of aqueous subduction fluids
lost by the associated crustal rocks during high-pressure (HP) metamorphism and retrogression. Dolomite-free and dolomite-bearing
peridotites share the same metamorphic evolution, from garnet- (HP) to spinel-facies (low-pressure, LP) conditions. Dolomite
and the texturally coexisting phases display equilibrium redistribution of rare earth elements and of incompatible trace elements
during HP and LP metamorphism; clinopyroxene and amphiboles from carbonate-free and carbonate-bearing peridotites have quite
similar compositions. These features indicate that the UZ mantle rocks equilibrated with the same metasomatic agents: aqueous
CO2-bearing fluids enriched in incompatible elements released by the crust. The P–T crystallization conditions of the dolomite peridotites (outside the field of carbonatite melt + amphibole peridotite coexistence),
a lack of textures indicating quench of carbonic melts, a lack of increase in modal clinopyroxene by reaction with such melts
and the observed amphibole increase at the expense of clinopyroxene, all suggest that dolomite formation was assisted by aqueous
CO2-bearing fluids. A comparison of the trace element compositions of carbonates and amphiboles from the UZ peridotites and from
peridotites metasomatized by carbonatite and/or carbon-bearing silicate melts does not help to unambiguously discriminate
between the different agents (fluids or melts). The few observed differences (lower trace element contents in the fluid-related
dolomite) may ultimately depend on the solute content of the metasomatic agent (CO2-bearing fluid versus carbonatite melt). This study provides strong evidence that C–O–H subduction fluids can produce ‘carbonatite-like’
assemblages in mantle rocks, thus being effective C carriers from the slab to the mantle wedge at relatively low P–T. If transported beyond the carbonate and amphibole solidus by further subduction, dolomite-bearing garnet + amphibole peridotites
like the ones from Ulten can become sources of carbonatite and/or C-bearing silicate melts in the mantle wedge.
Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.
In memory of Lauro Morten 1941–2006. 相似文献
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Simone Tumiati Gaston Godard Silvana Martin Urs Kltzli Damiano Monticelli 《Lithos》2007,94(1-4):148-167
The Nonsberg–Ultental Region of northern Italy contains a Palaeozoic mélange that was partially subducted during the Variscan orogeny. This mélange is constituted mainly by metapelites characterized by shale-type REE-patterns, displaying partial melting which began under high-pressure conditions. The resulting migmatites enclose minor slivers of mantle-wedge peridotites that have been incorporated into the mélange during subduction. Peridotites display important large ion lithophile elements (LILE) enrichment consequent to amphibole recrystallization contemporaneously with metapelite migmatization at P ≈ 2.7 GPa and T ≈ 850 °C in the garnet–peridotite field. Crustal and mantle (ultramafic) rocks of the mélange display the same Sm–Nd ages of about 330 ± 6 Ma, which dates both the metamorphic peak and the migmatization event. The zircon U–Pb age of the metasomatic amphibolitic contact between garnet peridotite and migmatite is identical (333.3 ± 2.4 Ma) within analytical errors. Therefore, metasomatism, migmatization and peak metamorphism are constrained to the same event. The presence of Cl-rich apatite and ferrokinoshitalite in the contact amphibolite, together with the trace-element patterns of peridotites, suggest that metasomatism was driven by Cl- and LILE-rich fluids derived from ocean water transported into the subduction zone by sediments and crustal rocks. These fluids interacted with the crust, prompting partial melting under water oversaturated conditions and partitioning LILE from the crust itself. Peridotites, which were well below their wet solidus temperature, could not melt but they recrystallized in the crustal mélange under garnet-facies conditions. Crustal fluids caused extensive hydration and LILE-enrichment in peridotites and severe Sm–Nd isotope disequilibrium between minerals, especially in the recrystallized peridotites. The proposed scenario suggests massive entrapment of crustal aqueous fluids at high-pressure conditions within subduction zones. 相似文献
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Simone Tumiati Martin Thni Paolo Nimis Silvana Martin Volkmar Mair 《Earth and Planetary Science Letters》2003,210(3-4):509-526
We have analyzed the Sm–Nd and Rb–Sr whole-rock and mineral isotope systematics of garnet peridotites and associated eclogites and migmatitic gneisses from the Nonsberg–Ulten zone of the Eastern Alps. The garnet peridotites include coarse-grained varieties, characterized by well-preserved to slightly modified mantle geochemical signatures, and finer-grained varieties enriched in amphibole and LILE. Hydration of some of the most strongly deformed, fine-grained peridotites by crustal fluids caused isotopic disequilibrium between the peridotite minerals, preventing accurate age determinations. The coarse-grained peridotites, the eclogites and the country migmatitic gneisses yield garnet–whole-rock and garnet–clinopyroxene Sm–Nd ages that indicate for all rock types an isotopic homogenization event at ca. 330 Ma. The similar ages suggest that all rock types shared a common history since the incorporation of the peridotites in the crust, and constrain the garnet-facies metamorphism of the peridotites, as well as partial melting of the crust, to an episode of crustal subduction at the end of the Variscan orogenic cycle. 相似文献
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