Fluorine partitioning between eclogitic garnet, clinopyroxene, and melt at upper mantle conditions

In this experimental study we obtained new mineral/melt (DF=cmineral/cmelt) partitioning data for fluorine in a bimineralic hydrous eclogite under Earth's upper mantle conditions (4–6GPa, 1460–1550°C). Omphacitic clinopyroxene displays mineral/melt partition coefficients between DF=0.056±0.005...

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Published in:Chemical geology 2016-10, Vol.437, p.88-97
Main Authors: Beyer, C., Klemme, S., Grützner, T., Ireland, T.R., Magee, C.W., Frost, D.J.
Format: Article
Language:English
Subjects:
Brackish
Crusts
Depletion
Element partitioning
Fluorine
Garnets
Halogen
Lamproite
Mantle
Marine
Melts
Multi-anvil
Partial melting
Partitioning
Partitions
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cited_by cdi_FETCH-LOGICAL-a511t-df8f1f6bf64c6cb90c3166d5c72303c06756a87e6167889bfa5140d2551941d83
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container_end_page 97
container_issue
container_start_page 88
container_title Chemical geology
container_volume 437
creator Beyer, C.
Klemme, S.
Grützner, T.
Ireland, T.R.
Magee, C.W.
Frost, D.J.
description In this experimental study we obtained new mineral/melt (DF=cmineral/cmelt) partitioning data for fluorine in a bimineralic hydrous eclogite under Earth's upper mantle conditions (4–6GPa, 1460–1550°C). Omphacitic clinopyroxene displays mineral/melt partition coefficients between DF=0.056±0.005 and DF=0.074±0.001. Garnet partition coefficients are consistently lower with an average partition coefficient of DF=0.016±0.003. We found that omphacitic clinopyroxene is the dominant nominally fluorine-free phase in subducted oceanic crust and hence omphacite is expected to be the major fluorine carrier during subduction of crust into the deeper mantle. Together with previously obtained partitioning data we propose that the oceanic crust can host more fluorine per mass unit than the underlying depleted oceanic mantle. If the majority of entrained fluorine is recycled into Earth's transition zone it is possible that the fluorine is either incorporated into high-pressure transition zone phases or released during high-pressure phase transformations and forming fluorine-rich small degree partial melts. Both scenarios are supported by elevated fluorine concentration in ocean island basalts, kimberlites, and lamproites. Combining the fluorine partitioning data with water partitioning data yields a plausible process to generate lamproitic magmas with a high F/H2O ratio. The enrichment of fluorine relative to H2O is triggered by multiple episodes of small degree melting that deplete the residual more in H2O than in fluorine, caused by the approximately three times smaller mineral-melt partition coefficients of H2O.
doi_str_mv 10.1016/j.chemgeo.2016.05.032
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subjects Brackish
Crusts
Depletion
Element partitioning
Fluorine
Garnets
Halogen
Lamproite
Mantle
Marine
Melts
Multi-anvil
Partial melting
Partitioning
Partitions
title Fluorine partitioning between eclogitic garnet, clinopyroxene, and melt at upper mantle conditions
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