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RESEARCH PRODUCT
New constraints on granulite facies metamorphism and melt production in the Lewisian Complex, northwest Scotland
Richard WhiteRichard WhiteYves FeiselRichard M. PalinTim E. JohnsonTim E. Johnsonsubject
GE010504 meteorology & atmospheric sciencesArcheanEarth sciencePartial meltingNDASMetamorphismPseudosectionThermocalcGeologyArchaeanPartial melting010502 geochemistry & geophysicsGranulite01 natural sciencesMineral resource classificationLewisian complexQE GeologyMafic phase equilibraGeochemistry and PetrologyFaciesQEGeology0105 earth and related environmental sciencesGE Environmental Sciencesdescription
The research carried out for this study was part of YF's Master Thesis at the Institute of Geoscience, Johannes Gutenberg University, Mainz, which provided the funding for fieldwork and laboratory analyses. TJ acknowledges support from Open Fund GPMR210704 from the State Key Lab for Geological Processes and Mineral Resources, China University of Geosciences, Wuhan. In this study we investigate the metamorphic history of the Assynt and Gruinard blocks of the Archaean Lewisian Complex, northwest Scotland, which are considered by some to represent discrete crustal terranes. For samples of mafic and intermediate rocks, phase diagrams were constructed in the Na2O-CaO‐K2O‐FeO‐MgO‐Al2O3-SiO2-H2O-TiO2-O2 (NCKFMASHTO) system using whole‐rock compositions. Our results indicate that all samples equilibrated at similar peak metamorphic conditions of ~8‐10 kbar and ~900‐1000°C, consistent with field evidence for in‐situ partial melting and the classic interpretation of the central region of the Lewisian Complex as representing a single crustal block. Melt reintegration modelling was employed in order to estimate probable protolith compositions. Phase equilibria calculated for these modelled undepleted precursors match well with those determined for a subsolidus amphibolite from Gairloch in the southern region of the Lewisian Complex. Both subsolidus lithologies exhibit similar phase relations and potential melt fertility, with both expected to produce orthopyroxene‐bearing hornblende‐granulites, with or without garnet, at the conditions inferred for the Badcallian metamorphic peak. For fully hydrated protoliths, prograde melting is predicted to first occur at ~620 °C and ~9.5 kbar, with up to 45% partial melt predicted to form at peak conditions in a closed‐system environment. Partial melts calculated for both compositions between 610 °C and 1050 °C are mostly trondhjemitic. Although the melt‐reintegrated granulite is predicted to produce more potassic (granitic) melts at ~700‐900 °C, the modelled melts are consistent with the measured compositions of felsic sheets from the central region Lewisian Complex. Postprint Peer reviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-04-22 |