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Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton. / Ionov, Dmitri A.; Doucet, Luc S.; Pogge von Strandmann, Philip A.E. и др.

в: Chemical Geology, Том 475, 25.12.2017, стр. 105-121.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Ionov, DA, Doucet, LS, Pogge von Strandmann, PAE, Golovin, AV & Korsakov, AV 2017, 'Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton', Chemical Geology, Том. 475, стр. 105-121. https://doi.org/10.1016/j.chemgeo.2017.10.038

APA

Ionov, D. A., Doucet, L. S., Pogge von Strandmann, P. A. E., Golovin, A. V., & Korsakov, A. V. (2017). Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton. Chemical Geology, 475, 105-121. https://doi.org/10.1016/j.chemgeo.2017.10.038

Vancouver

Ionov DA, Doucet LS, Pogge von Strandmann PAE, Golovin AV, Korsakov AV. Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton. Chemical Geology. 2017 дек. 25;475:105-121. doi: 10.1016/j.chemgeo.2017.10.038

Author

Ionov, Dmitri A. ; Doucet, Luc S. ; Pogge von Strandmann, Philip A.E. и др. / Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton. в: Chemical Geology. 2017 ; Том 475. стр. 105-121.

BibTeX

@article{d4784161171544bfaf78fd59f4d32f24,
title = "Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton",
abstract = "We report the concentrations ([Li]) and isotopic compositions of Li in mineral separates and bulk rocks obtained by MC-ICPMS for 14 previously studied garnet and spinel peridotite xenoliths from the Udachnaya kimberlite in the central Siberian craton as well as major and trace element compositions for a new suite of 13 deformed garnet peridotites. The deformed Udachnaya peridotites occur at > 5 GPa; they are metasomatized residues of melt extraction, which as a group experienced greater modal and chemical enrichments than coarse peridotites. We identify two sub-groups of the deformed peridotites: (a) mainly cryptically metasomatized (similar to coarse peridotites) with relatively low modal cpx (< 6%) and garnet (< 7%), low Ca and high Mg#, sinusoidal REE patterns in garnet, and chemically unequilibrated garnet and cpx; (b) modally metasomatized with more cpx and garnet, higher Ca, Fe and Ti, and equilibrated garnet and cpx. The chemical enrichments are not proportional to deformation degrees. The deformation in the lower lithosphere is caused by a combination of localized stress, heating and fluid ingress from the pathways of ascending proto-kimberlite melts, with metasomatic media evolving due to reactions with wall rocks. Mg-rich olivine in spinel and coarse garnet Udachnaya peridotites has 1.2–1.9 ppm Li and δ7Li of 1.2–5.0‰, i.e. close to olivine in equilibrated fertile to depleted off-craton mantle peridotites from literature data, whereas olivine from the deformed peridotites has higher [Li] (2.4–7.5 ppm) and a broader range of δ7Li (1.8–11.6‰), which we attribute to pre-eruption metasomatism. [Li] in opx is higher than in coexisting olivine while Δ7LiOl-Opx (δ7LiOl − δ7LiOpx) ranges from − 6.6 to 7.8‰, indicating disequilibrium inter-mineral [Li] and Li-isotope partitioning. We relate these Li systematics to interaction of lithospheric peridotites with fluids or melts that are either precursors of kimberlite magmatism or products of their fractionation and/or reaction with host mantle. The melts rich in Na and carbonates infiltrated, heated and weakened wall-rock peridotites to facilitate their deformation as well as produce high [Li] and variable, but mainly high, δ7Li in olivine. The carbonate-rich melts preferentially reacted with the opx without achieving inter-mineral equilibrium because opx is consumed by such melts, and because of small volumes and uneven distribution of the metasomatic media, as well as short time spans between the melt infiltration and the capture of the wall-rock fragments by incoming portions of ascending kimberlite magma as xenoliths. Trapped interstitial liquid solidified as cryptic components responsible for high [Li] and the lack of δ7Li balance between olivine and opx, and bulk rocks. Unaltered δ26Mg values (0.20–0.26‰) measured in several olivine separates show no effects of the metasomatism on Mg-isotopes, apparently due to high Mg in the peridotites.",
keywords = "Deformation, Li isotopes, Lithium, Lithophile trace elements, Lithospheric mantle, Peridotite xenolith, Siberian craton, SOUTH-AFRICA, RE-OS ISOTOPE, LITHIUM ABUNDANCES, PERIDOTITE XENOLITHS, UNALTERED KIMBERLITES, SHEARED PERIDOTITE, U-PB, SPINEL HARZBURGITE XENOLITHS, TRACE-ELEMENT COMPOSITIONS, UDACHNAYA-EAST PIPE",
author = "Ionov, {Dmitri A.} and Doucet, {Luc S.} and {Pogge von Strandmann}, {Philip A.E.} and Golovin, {Alexander V.} and Korsakov, {Andrey V.}",
note = "Publisher Copyright: {\textcopyright} 2017 Elsevier B.V.",
year = "2017",
month = dec,
day = "25",
doi = "10.1016/j.chemgeo.2017.10.038",
language = "English",
volume = "475",
pages = "105--121",
journal = "Chemical Geology",
issn = "0009-2541",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Links between deformation, chemical enrichments and Li-isotope compositions in the lithospheric mantle of the central Siberian craton

AU - Ionov, Dmitri A.

AU - Doucet, Luc S.

AU - Pogge von Strandmann, Philip A.E.

AU - Golovin, Alexander V.

AU - Korsakov, Andrey V.

N1 - Publisher Copyright: © 2017 Elsevier B.V.

PY - 2017/12/25

Y1 - 2017/12/25

N2 - We report the concentrations ([Li]) and isotopic compositions of Li in mineral separates and bulk rocks obtained by MC-ICPMS for 14 previously studied garnet and spinel peridotite xenoliths from the Udachnaya kimberlite in the central Siberian craton as well as major and trace element compositions for a new suite of 13 deformed garnet peridotites. The deformed Udachnaya peridotites occur at > 5 GPa; they are metasomatized residues of melt extraction, which as a group experienced greater modal and chemical enrichments than coarse peridotites. We identify two sub-groups of the deformed peridotites: (a) mainly cryptically metasomatized (similar to coarse peridotites) with relatively low modal cpx (< 6%) and garnet (< 7%), low Ca and high Mg#, sinusoidal REE patterns in garnet, and chemically unequilibrated garnet and cpx; (b) modally metasomatized with more cpx and garnet, higher Ca, Fe and Ti, and equilibrated garnet and cpx. The chemical enrichments are not proportional to deformation degrees. The deformation in the lower lithosphere is caused by a combination of localized stress, heating and fluid ingress from the pathways of ascending proto-kimberlite melts, with metasomatic media evolving due to reactions with wall rocks. Mg-rich olivine in spinel and coarse garnet Udachnaya peridotites has 1.2–1.9 ppm Li and δ7Li of 1.2–5.0‰, i.e. close to olivine in equilibrated fertile to depleted off-craton mantle peridotites from literature data, whereas olivine from the deformed peridotites has higher [Li] (2.4–7.5 ppm) and a broader range of δ7Li (1.8–11.6‰), which we attribute to pre-eruption metasomatism. [Li] in opx is higher than in coexisting olivine while Δ7LiOl-Opx (δ7LiOl − δ7LiOpx) ranges from − 6.6 to 7.8‰, indicating disequilibrium inter-mineral [Li] and Li-isotope partitioning. We relate these Li systematics to interaction of lithospheric peridotites with fluids or melts that are either precursors of kimberlite magmatism or products of their fractionation and/or reaction with host mantle. The melts rich in Na and carbonates infiltrated, heated and weakened wall-rock peridotites to facilitate their deformation as well as produce high [Li] and variable, but mainly high, δ7Li in olivine. The carbonate-rich melts preferentially reacted with the opx without achieving inter-mineral equilibrium because opx is consumed by such melts, and because of small volumes and uneven distribution of the metasomatic media, as well as short time spans between the melt infiltration and the capture of the wall-rock fragments by incoming portions of ascending kimberlite magma as xenoliths. Trapped interstitial liquid solidified as cryptic components responsible for high [Li] and the lack of δ7Li balance between olivine and opx, and bulk rocks. Unaltered δ26Mg values (0.20–0.26‰) measured in several olivine separates show no effects of the metasomatism on Mg-isotopes, apparently due to high Mg in the peridotites.

AB - We report the concentrations ([Li]) and isotopic compositions of Li in mineral separates and bulk rocks obtained by MC-ICPMS for 14 previously studied garnet and spinel peridotite xenoliths from the Udachnaya kimberlite in the central Siberian craton as well as major and trace element compositions for a new suite of 13 deformed garnet peridotites. The deformed Udachnaya peridotites occur at > 5 GPa; they are metasomatized residues of melt extraction, which as a group experienced greater modal and chemical enrichments than coarse peridotites. We identify two sub-groups of the deformed peridotites: (a) mainly cryptically metasomatized (similar to coarse peridotites) with relatively low modal cpx (< 6%) and garnet (< 7%), low Ca and high Mg#, sinusoidal REE patterns in garnet, and chemically unequilibrated garnet and cpx; (b) modally metasomatized with more cpx and garnet, higher Ca, Fe and Ti, and equilibrated garnet and cpx. The chemical enrichments are not proportional to deformation degrees. The deformation in the lower lithosphere is caused by a combination of localized stress, heating and fluid ingress from the pathways of ascending proto-kimberlite melts, with metasomatic media evolving due to reactions with wall rocks. Mg-rich olivine in spinel and coarse garnet Udachnaya peridotites has 1.2–1.9 ppm Li and δ7Li of 1.2–5.0‰, i.e. close to olivine in equilibrated fertile to depleted off-craton mantle peridotites from literature data, whereas olivine from the deformed peridotites has higher [Li] (2.4–7.5 ppm) and a broader range of δ7Li (1.8–11.6‰), which we attribute to pre-eruption metasomatism. [Li] in opx is higher than in coexisting olivine while Δ7LiOl-Opx (δ7LiOl − δ7LiOpx) ranges from − 6.6 to 7.8‰, indicating disequilibrium inter-mineral [Li] and Li-isotope partitioning. We relate these Li systematics to interaction of lithospheric peridotites with fluids or melts that are either precursors of kimberlite magmatism or products of their fractionation and/or reaction with host mantle. The melts rich in Na and carbonates infiltrated, heated and weakened wall-rock peridotites to facilitate their deformation as well as produce high [Li] and variable, but mainly high, δ7Li in olivine. The carbonate-rich melts preferentially reacted with the opx without achieving inter-mineral equilibrium because opx is consumed by such melts, and because of small volumes and uneven distribution of the metasomatic media, as well as short time spans between the melt infiltration and the capture of the wall-rock fragments by incoming portions of ascending kimberlite magma as xenoliths. Trapped interstitial liquid solidified as cryptic components responsible for high [Li] and the lack of δ7Li balance between olivine and opx, and bulk rocks. Unaltered δ26Mg values (0.20–0.26‰) measured in several olivine separates show no effects of the metasomatism on Mg-isotopes, apparently due to high Mg in the peridotites.

KW - Deformation

KW - Li isotopes

KW - Lithium

KW - Lithophile trace elements

KW - Lithospheric mantle

KW - Peridotite xenolith

KW - Siberian craton

KW - SOUTH-AFRICA

KW - RE-OS ISOTOPE

KW - LITHIUM ABUNDANCES

KW - PERIDOTITE XENOLITHS

KW - UNALTERED KIMBERLITES

KW - SHEARED PERIDOTITE

KW - U-PB

KW - SPINEL HARZBURGITE XENOLITHS

KW - TRACE-ELEMENT COMPOSITIONS

KW - UDACHNAYA-EAST PIPE

UR - http://www.scopus.com/inward/record.url?scp=85032957583&partnerID=8YFLogxK

U2 - 10.1016/j.chemgeo.2017.10.038

DO - 10.1016/j.chemgeo.2017.10.038

M3 - Article

AN - SCOPUS:85032957583

VL - 475

SP - 105

EP - 121

JO - Chemical Geology

JF - Chemical Geology

SN - 0009-2541

ER -

ID: 9400072