Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism

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Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism. / Shatskiy, Anton; Bekhtenova, Altyna; Podborodnikov, Ivan V. et al.

In: Gondwana Research, Vol. 103, 03.2022, p. 188-204.

Research output: Contribution to journal › Article › peer-review

Harvard

Shatskiy, A, Bekhtenova, A, Podborodnikov, IV, Arefiev, AV, Vinogradova, YG & Litasov, KD 2022, 'Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism', Gondwana Research, vol. 103, pp. 188-204. https://doi.org/10.1016/j.gr.2021.10.016

APA

Shatskiy, A., Bekhtenova, A., Podborodnikov, I. V., Arefiev, A. V., Vinogradova, Y. G., & Litasov, K. D. (2022). Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism. Gondwana Research, 103, 188-204. https://doi.org/10.1016/j.gr.2021.10.016

Vancouver

Shatskiy A, Bekhtenova A, Podborodnikov IV, Arefiev AV, Vinogradova YG, Litasov KD. Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism. Gondwana Research. 2022 Mar;103:188-204. doi: 10.1016/j.gr.2021.10.016

Author

Shatskiy, Anton ; Bekhtenova, Altyna ; Podborodnikov, Ivan V. et al. / Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism. In: Gondwana Research. 2022 ; Vol. 103. pp. 188-204.

BibTeX

@article{c40c53b8638f4f5d9c107135246d90e9,

title = "Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism",

abstract = "The interaction of natural eclogite (Ecl) with synthetic hydrous carbonate melts with Na:K = 0:1 (KH2) and 1:1 (NKH2) was studied in multianvil experiments at 3–6 GPa and 850–1250 °C. The interaction with KH2 consumes garnet and clinopyroxene producing phlogopite and calcite-dolomite solid solution. Besides, the interaction yields a decrease in the jadeite component of clinopyroxene, evolving eclogite toward pyroxenite. This is consistent with a metasomatic alteration of eclogite xenoliths, manifested as Na-poor “spongy” clinopyroxene, replacing primary omphacite, and kelyphitic rims around garnet, containing phlogopite and carbonates. The interaction with NKH2 also produces phlogopite and carbonate, but the latter is more magnesian and represented by magnesite, above the solidus, and magnesite + dolomite below the solidus. The interaction with NKH2 increases the jadeite component in clinopyroxene and grossular component in garnet, evolving eclogite Group A to eclogite Group B. The studied systems have H2O/K2O = 2, like that in phlogopite, and therefore correspond to carbonated phlogopite eclogite under fluid-absent conditions. Based on the obtained results its solidus is situated near 1050 °C at 3 GPa and decreases to 950 °C at 6 GPa. Thus, hydrous K- and Na-K-carbonatite melts can coexist with eclogite in SCLM at depths exceeding 120–170 km, and solidify as temperature decreases below 950–1050 °C according to the following solidus reactions: pyrope + diopside + melt → phlogopite + dolomite, below 6 GPa, and pyrope + diopside + melt → phlogopite + magnesite + grossular, at 6 GPa. The melting reaction, involving phlogopite and dolomite, suggests the partial melting at the peak of ultrahigh-pressure metamorphism (UHPM) during continent–continent plate collision. The prograde P-T path of UHPM crosses the solidus of clinopyroxene + garnet + phlogopite + dolomite assemblage at 4.7–5.2 GPa and 970–990 °C and yields the formation of hydrous K-carbonatite melt-fluid in situ. This melt could be responsible for the formation of K-bearing clinopyroxenes and microdiamonds in the UHPM marbles in the Kokchetav massif, Kazakhstan. The retrograde P-T path intersects the solidus that has a negative Clapeyron slope in the diamond stability field. Thus, the hydrous K-carbonatite melt should disappear soon after the peak of metamorphism reacting with garnet to produce Ca-Mg carbonates and phlogopite.",

keywords = "Earth's mantle, Eclogite solidus, High-pressure experiment, Mantle metasomatism, Mantle partial melting",

author = "Anton Shatskiy and Altyna Bekhtenova and Podborodnikov, {Ivan V.} and Arefiev, {Anton V.} and Vinogradova, {Yulia G.} and Litasov, {Konstantin D.}",

note = "Funding Information: We are grateful to S. Tappe for editorial handling; three anonymous reviewers for constructive reviews; N.V. Sobolev, L.N. Pokhilenko, A.V. Korsakov for helpful comments, V.S. Shatsky and A.L. Ragozin for providing natural eclogite and discussion; N.S. Karmanov, A.T. Titov, and M.V. Khlestov for assistance in the analytical works. The SEM and EDS studies of experimental samples were performed in the Analytical Center for multi-elemental and isotope research SB RAS. This work is financially supported by Russian Science Foundation (project No 21-77-10057). Publisher Copyright: {\textcopyright} 2021 International Association for Gondwana Research",

year = "2022",

month = mar,

doi = "10.1016/j.gr.2021.10.016",

language = "English",

volume = "103",

pages = "188--204",

journal = "Gondwana Research",

issn = "1342-937X",

publisher = "Elsevier Science Inc.",

}

RIS

TY - JOUR

T1 - Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism

AU - Shatskiy, Anton

AU - Bekhtenova, Altyna

AU - Podborodnikov, Ivan V.

AU - Arefiev, Anton V.

AU - Vinogradova, Yulia G.

AU - Litasov, Konstantin D.

N1 - Funding Information: We are grateful to S. Tappe for editorial handling; three anonymous reviewers for constructive reviews; N.V. Sobolev, L.N. Pokhilenko, A.V. Korsakov for helpful comments, V.S. Shatsky and A.L. Ragozin for providing natural eclogite and discussion; N.S. Karmanov, A.T. Titov, and M.V. Khlestov for assistance in the analytical works. The SEM and EDS studies of experimental samples were performed in the Analytical Center for multi-elemental and isotope research SB RAS. This work is financially supported by Russian Science Foundation (project No 21-77-10057). Publisher Copyright: © 2021 International Association for Gondwana Research

PY - 2022/3

Y1 - 2022/3

N2 - The interaction of natural eclogite (Ecl) with synthetic hydrous carbonate melts with Na:K = 0:1 (KH2) and 1:1 (NKH2) was studied in multianvil experiments at 3–6 GPa and 850–1250 °C. The interaction with KH2 consumes garnet and clinopyroxene producing phlogopite and calcite-dolomite solid solution. Besides, the interaction yields a decrease in the jadeite component of clinopyroxene, evolving eclogite toward pyroxenite. This is consistent with a metasomatic alteration of eclogite xenoliths, manifested as Na-poor “spongy” clinopyroxene, replacing primary omphacite, and kelyphitic rims around garnet, containing phlogopite and carbonates. The interaction with NKH2 also produces phlogopite and carbonate, but the latter is more magnesian and represented by magnesite, above the solidus, and magnesite + dolomite below the solidus. The interaction with NKH2 increases the jadeite component in clinopyroxene and grossular component in garnet, evolving eclogite Group A to eclogite Group B. The studied systems have H2O/K2O = 2, like that in phlogopite, and therefore correspond to carbonated phlogopite eclogite under fluid-absent conditions. Based on the obtained results its solidus is situated near 1050 °C at 3 GPa and decreases to 950 °C at 6 GPa. Thus, hydrous K- and Na-K-carbonatite melts can coexist with eclogite in SCLM at depths exceeding 120–170 km, and solidify as temperature decreases below 950–1050 °C according to the following solidus reactions: pyrope + diopside + melt → phlogopite + dolomite, below 6 GPa, and pyrope + diopside + melt → phlogopite + magnesite + grossular, at 6 GPa. The melting reaction, involving phlogopite and dolomite, suggests the partial melting at the peak of ultrahigh-pressure metamorphism (UHPM) during continent–continent plate collision. The prograde P-T path of UHPM crosses the solidus of clinopyroxene + garnet + phlogopite + dolomite assemblage at 4.7–5.2 GPa and 970–990 °C and yields the formation of hydrous K-carbonatite melt-fluid in situ. This melt could be responsible for the formation of K-bearing clinopyroxenes and microdiamonds in the UHPM marbles in the Kokchetav massif, Kazakhstan. The retrograde P-T path intersects the solidus that has a negative Clapeyron slope in the diamond stability field. Thus, the hydrous K-carbonatite melt should disappear soon after the peak of metamorphism reacting with garnet to produce Ca-Mg carbonates and phlogopite.

AB - The interaction of natural eclogite (Ecl) with synthetic hydrous carbonate melts with Na:K = 0:1 (KH2) and 1:1 (NKH2) was studied in multianvil experiments at 3–6 GPa and 850–1250 °C. The interaction with KH2 consumes garnet and clinopyroxene producing phlogopite and calcite-dolomite solid solution. Besides, the interaction yields a decrease in the jadeite component of clinopyroxene, evolving eclogite toward pyroxenite. This is consistent with a metasomatic alteration of eclogite xenoliths, manifested as Na-poor “spongy” clinopyroxene, replacing primary omphacite, and kelyphitic rims around garnet, containing phlogopite and carbonates. The interaction with NKH2 also produces phlogopite and carbonate, but the latter is more magnesian and represented by magnesite, above the solidus, and magnesite + dolomite below the solidus. The interaction with NKH2 increases the jadeite component in clinopyroxene and grossular component in garnet, evolving eclogite Group A to eclogite Group B. The studied systems have H2O/K2O = 2, like that in phlogopite, and therefore correspond to carbonated phlogopite eclogite under fluid-absent conditions. Based on the obtained results its solidus is situated near 1050 °C at 3 GPa and decreases to 950 °C at 6 GPa. Thus, hydrous K- and Na-K-carbonatite melts can coexist with eclogite in SCLM at depths exceeding 120–170 km, and solidify as temperature decreases below 950–1050 °C according to the following solidus reactions: pyrope + diopside + melt → phlogopite + dolomite, below 6 GPa, and pyrope + diopside + melt → phlogopite + magnesite + grossular, at 6 GPa. The melting reaction, involving phlogopite and dolomite, suggests the partial melting at the peak of ultrahigh-pressure metamorphism (UHPM) during continent–continent plate collision. The prograde P-T path of UHPM crosses the solidus of clinopyroxene + garnet + phlogopite + dolomite assemblage at 4.7–5.2 GPa and 970–990 °C and yields the formation of hydrous K-carbonatite melt-fluid in situ. This melt could be responsible for the formation of K-bearing clinopyroxenes and microdiamonds in the UHPM marbles in the Kokchetav massif, Kazakhstan. The retrograde P-T path intersects the solidus that has a negative Clapeyron slope in the diamond stability field. Thus, the hydrous K-carbonatite melt should disappear soon after the peak of metamorphism reacting with garnet to produce Ca-Mg carbonates and phlogopite.

KW - Earth's mantle

KW - Eclogite solidus

KW - High-pressure experiment

KW - Mantle metasomatism

KW - Mantle partial melting

UR - http://www.scopus.com/inward/record.url?scp=85121259913&partnerID=8YFLogxK

U2 - 10.1016/j.gr.2021.10.016

DO - 10.1016/j.gr.2021.10.016

M3 - Article

AN - SCOPUS:85121259913

VL - 103

SP - 188

EP - 204

JO - Gondwana Research

JF - Gondwana Research

SN - 1342-937X

ER -

ID: 35033716