Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma

Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma

The most abundant terrestrial lavas, mid-ocean ridge basalt (MORB) and ocean island basalt (OIB), are commonly considered to be derived from a depleted MORB-mantle component (DMM) and more specific, variably enriched mantle plume sources. However, findings of oceanic lavas and mafic cumulates issued...

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Main Authors: Anastassia Y. Borisova, Nail R. Zagrtdenov, Michael J. Toplis, Georges Ceuleneer, Oleg G. Safonov, Gleb S. Pokrovski, Klaus Peter Jochum, Brigitte Stoll, Ulrike Weis, Svyatoslav Shcheka, Andrey Y. Bychkov
Format: Article
Language:English
Published: Frontiers Media S.A. 2020-04-01
Series:Frontiers in Earth Science
Subjects:
hydrated peridotite
serpentinite
basaltic melt
assimilation
MORB
melt–rock interaction
Online Access:https://www.frontiersin.org/article/10.3389/feart.2020.00084/full
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author Anastassia Y. Borisova
Anastassia Y. Borisova
Nail R. Zagrtdenov
Michael J. Toplis
Georges Ceuleneer
Oleg G. Safonov
Oleg G. Safonov
Oleg G. Safonov
Gleb S. Pokrovski
Klaus Peter Jochum
Brigitte Stoll
Ulrike Weis
Svyatoslav Shcheka
Andrey Y. Bychkov
spellingShingle Anastassia Y. Borisova
Anastassia Y. Borisova
Nail R. Zagrtdenov
Michael J. Toplis
Georges Ceuleneer
Oleg G. Safonov
Oleg G. Safonov
Oleg G. Safonov
Gleb S. Pokrovski
Klaus Peter Jochum
Brigitte Stoll
Ulrike Weis
Svyatoslav Shcheka
Andrey Y. Bychkov
Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma
Frontiers in Earth Science
hydrated peridotite
serpentinite
basaltic melt
assimilation
MORB
melt–rock interaction
author_facet Anastassia Y. Borisova
Anastassia Y. Borisova
Nail R. Zagrtdenov
Michael J. Toplis
Georges Ceuleneer
Oleg G. Safonov
Oleg G. Safonov
Oleg G. Safonov
Gleb S. Pokrovski
Klaus Peter Jochum
Brigitte Stoll
Ulrike Weis
Svyatoslav Shcheka
Andrey Y. Bychkov
author_sort Anastassia Y. Borisova
title Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma
title_short Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma
title_full Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma
title_fullStr Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma
title_full_unstemmed Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic Magma
title_sort hydrated peridotite–basaltic melt interaction part ii: fast assimilation of serpentinized mantle by basaltic magma
publisher Frontiers Media S.A.
series Frontiers in Earth Science
issn 2296-6463
publishDate 2020-04-01
description The most abundant terrestrial lavas, mid-ocean ridge basalt (MORB) and ocean island basalt (OIB), are commonly considered to be derived from a depleted MORB-mantle component (DMM) and more specific, variably enriched mantle plume sources. However, findings of oceanic lavas and mafic cumulates issued from melts, enriched in chlorine and having a radiogenic 87Sr/86Sr ratio, can be attributed to an interaction between the asthenosphere-derived melts and lithospheric peridotite variably hydrated due to penetration of hydrothermal water down to and below Moho level. To constrain mechanisms and rates responsible for the interaction, we report results of 15 experiments of reaction between serpentinite and tholeiitic basaltic melt at 0.2–1.0 GPa and 1250–1300°C. Results show that the reaction proceeds via a multi-stage mechanism: (i) transformation of serpentinite into Cr-rich spinel-bearing harzburgite (Fo92–95 mol.%) containing pore fluid, (ii) partial melting and dissolution of the harzburgite assemblage with formation of interstitial hydrous melts (up to 57–60 wt% of SiO2 contents at 0.5 GPa pressure), and (iii) final assimilation of the Cr-rich spinel-bearing harzburgite/dunite and formation of hybrid basaltic melts with 12–13 wt.% of MgO and elevated Cr (up to ∼500 ppm) and Ni (up to ∼200 ppm) contents. Assimilation of serpentinite by basaltic melt may occur under elevated melt/rock ratios (>2) and may lead to chromitite formation. We show that hybrid magmas produced by the progressive assimilation of serpentinized lithospheric mantle may be recognized by high Mg-numbers and high Cr and Ni contents of olivine and pyroxenes, an excess of SiO2, H2O, and halogens in the melts, and some unusual isotopic composition (e.g., radiogenic 87Sr/86Sr, non-mantle δ18O, and low 3He/4He). Our experiments provide evidence that MORB and high-Mg-Cr orthopyroxene-rich cumulates depleted in incompatible elements can be produced from common mid-ocean ridge basaltic melts modified by reaction with hydrated lithospheric peridotite. We established that the rate of assimilation of serpentinized peridotite is controlled by silica diffusion in the reacting hydrous basaltic melt. Our study challenges traditional interpretation of the variations in MORB and OIB chemical and isotopic composition in terms of deep mantle plume source heterogeneities or/and degrees of partial melting.
topic hydrated peridotite
serpentinite
basaltic melt
assimilation
MORB
melt–rock interaction
url https://www.frontiersin.org/article/10.3389/feart.2020.00084/full
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spelling doaj-d97e5f5d6e004ddebe0368cb933624ff2020-11-25T03:36:23ZengFrontiers Media S.A.Frontiers in Earth Science2296-64632020-04-01810.3389/feart.2020.00084520716Hydrated Peridotite–Basaltic Melt Interaction Part II: Fast Assimilation of Serpentinized Mantle by Basaltic MagmaAnastassia Y. Borisova0Anastassia Y. Borisova1Nail R. Zagrtdenov2Michael J. Toplis3Georges Ceuleneer4Oleg G. Safonov5Oleg G. Safonov6Oleg G. Safonov7Gleb S. Pokrovski8Klaus Peter Jochum9Brigitte Stoll10Ulrike Weis11Svyatoslav Shcheka12Andrey Y. Bychkov13Géosciences Environnement Toulouse, GET, Université de Toulouse, CNRS, IRD, UPS, Toulouse, FranceGeological Department, Lomonosov Moscow State University, Moscow, RussiaGéosciences Environnement Toulouse, GET, Université de Toulouse, CNRS, IRD, UPS, Toulouse, FranceInstitut de Recherche en Astrophysique et Planétologie (IRAP) UPS OMP – CNRS – CNES, Toulouse, FranceGéosciences Environnement Toulouse, GET, Université de Toulouse, CNRS, IRD, UPS, Toulouse, FranceGeological Department, Lomonosov Moscow State University, Moscow, RussiaKorzhinskii Institute of Experimental Mineralogy, Chernogolovka, RussiaDepartment of Geology, University of Johannesburg, Johannesburg, South AfricaGéosciences Environnement Toulouse, GET, Université de Toulouse, CNRS, IRD, UPS, Toulouse, FranceClimate Geochemistry Department, Max Planck Institute for Chemistry, Mainz, GermanyClimate Geochemistry Department, Max Planck Institute for Chemistry, Mainz, GermanyClimate Geochemistry Department, Max Planck Institute for Chemistry, Mainz, GermanyBavarian Research Institute of Experimental Geochemistry and Geophysics (BGI), University of Bayreuth, Bayreuth, GermanyGeological Department, Lomonosov Moscow State University, Moscow, RussiaThe most abundant terrestrial lavas, mid-ocean ridge basalt (MORB) and ocean island basalt (OIB), are commonly considered to be derived from a depleted MORB-mantle component (DMM) and more specific, variably enriched mantle plume sources. However, findings of oceanic lavas and mafic cumulates issued from melts, enriched in chlorine and having a radiogenic 87Sr/86Sr ratio, can be attributed to an interaction between the asthenosphere-derived melts and lithospheric peridotite variably hydrated due to penetration of hydrothermal water down to and below Moho level. To constrain mechanisms and rates responsible for the interaction, we report results of 15 experiments of reaction between serpentinite and tholeiitic basaltic melt at 0.2–1.0 GPa and 1250–1300°C. Results show that the reaction proceeds via a multi-stage mechanism: (i) transformation of serpentinite into Cr-rich spinel-bearing harzburgite (Fo92–95 mol.%) containing pore fluid, (ii) partial melting and dissolution of the harzburgite assemblage with formation of interstitial hydrous melts (up to 57–60 wt% of SiO2 contents at 0.5 GPa pressure), and (iii) final assimilation of the Cr-rich spinel-bearing harzburgite/dunite and formation of hybrid basaltic melts with 12–13 wt.% of MgO and elevated Cr (up to ∼500 ppm) and Ni (up to ∼200 ppm) contents. Assimilation of serpentinite by basaltic melt may occur under elevated melt/rock ratios (>2) and may lead to chromitite formation. We show that hybrid magmas produced by the progressive assimilation of serpentinized lithospheric mantle may be recognized by high Mg-numbers and high Cr and Ni contents of olivine and pyroxenes, an excess of SiO2, H2O, and halogens in the melts, and some unusual isotopic composition (e.g., radiogenic 87Sr/86Sr, non-mantle δ18O, and low 3He/4He). Our experiments provide evidence that MORB and high-Mg-Cr orthopyroxene-rich cumulates depleted in incompatible elements can be produced from common mid-ocean ridge basaltic melts modified by reaction with hydrated lithospheric peridotite. We established that the rate of assimilation of serpentinized peridotite is controlled by silica diffusion in the reacting hydrous basaltic melt. Our study challenges traditional interpretation of the variations in MORB and OIB chemical and isotopic composition in terms of deep mantle plume source heterogeneities or/and degrees of partial melting.https://www.frontiersin.org/article/10.3389/feart.2020.00084/fullhydrated peridotiteserpentinitebasaltic meltassimilationMORBmelt–rock interaction

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