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dc.contributor.authorSun, Wei-dong
dc.contributor.authorHawkesworth, Chris J.
dc.contributor.authorYao, Chao
dc.contributor.authorZhang, Chan-chan
dc.contributor.authorHuang, Rui-fang
dc.contributor.authorLiu, Xi
dc.contributor.authorSun, Xin-lei
dc.contributor.authorIreland, Trevor
dc.contributor.authorSong, Mao-shuang
dc.contributor.authorLing, Ming-xing
dc.contributor.authorDing, Xing
dc.contributor.authorZhang, Zhao-feng
dc.contributor.authorFan, Wei-ming
dc.contributor.authorWu, Zhong-qing
dc.identifier.citationSun , W , Hawkesworth , C J , Yao , C , Zhang , C , Huang , R , Liu , X , Sun , X , Ireland , T , Song , M , Ling , M , Ding , X , Zhang , Z , Fan , W & Wu , Z 2018 , ' Carbonated mantle domains at the base of the Earth's transition zone ' , Chemical Geology , vol. 478 , pp. 69-75 .
dc.identifier.otherPURE: 250652268
dc.identifier.otherPURE UUID: 2bde1ae1-b409-48eb-a5f3-da7609f119fe
dc.identifier.otherRIS: urn:E1E1518374A0E157D09DB7A9E234BEAF
dc.identifier.otherScopus: 85027397607
dc.identifier.otherWOS: 000422753100006
dc.descriptionThis study was supported by National Key R&D Program of China 2016YFC0600408, CASXDB18020000, NSFC91328204 to W.D.S., State Key Development Program of Basic Research of China (2014CB845905), NSFC41274087 to Z.Q.W. 41090371 to X.L. TRI acknowledges a Chinese Academy of Sciences President's International Fellowship for visiting scientists Grant No. 2015VEA003.en
dc.description.abstractThe oxygen fugacity of the upper mantle is 3–4 orders of magnitude higher than that of the lower mantle and this has been attributed to Fe2+ disproportionating into Fe3+ plus Fe0 at pressures > 24 GPa. The upper mantle might therefore have been expected to have evolved to more oxidizing compositions through geological time, but it appears that the oxygen fugacity of the upper mantle has remained constant for the last 3.5 billion years. Thus, it indicates that the mantle has been actively buffered from the accumulation of Fe3+, and that this is linked to oxidation of diamond to carbonate coupled with reduction of Fe3+ to Fe2+. When subducted plates penetrate into the lower mantle, compensational upwelling transports bridgmanite into the transition zone, where it breaks down to ringwoodite and majorite, releasing the ferric iron. The system returns to equilibrium through oxidation of diamond. Early in Earth history, diamond may have been enriched at the base of the transition zone in the Magma Ocean, because it is denser than peridotite melts at depths shallower than 660 km, and it is more buoyant below. Ongoing oxidation of diamond forms carbonate, leading to relatively high carbonate concentrations in the source of ocean island basalts.
dc.relation.ispartofChemical Geologyen
dc.rights© 2017 Elsevier Ltd. All rights reserved. This work has been made available online in accordance with the publisher’s policies. This is the author created, accepted version manuscript following peer review and may differ slightly from the final published version. The final published version of this work is available at
dc.subjectCarbon cycleen
dc.subjectCarbon concentrationen
dc.subjectFirst-principles calculationsen
dc.subjectEarth mantleen
dc.subjectQE Geologyen
dc.subjectGE Environmental Sciencesen
dc.titleCarbonated mantle domains at the base of the Earth's transition zoneen
dc.typeJournal articleen
dc.contributor.institutionUniversity of St Andrews.School of Earth & Environmental Sciencesen
dc.description.statusPeer revieweden

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