Rise of mantle oxidation by Neoarchean subduction in the North China Craton

•Oxygen fugacity of neoarchean subduction-metasomatized peridotites is measured.•Neoarchean subduction zone mantle in the North China Craton was oxidized.•Neoarchean rise of mantle oxidation in the North China Craton was caused by plate subduction. The Archean mantle redox state played an important...

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Published in:Earth and planetary science letters 2024-11, Vol.646, p.119006, Article 119006
Main Authors: Wu, Zhenzhu, Wang, Chao, Allen, Mark B., Tang, Ming, Chen, Yi, Jia, Lihui, Song, Shuguang
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Language:English
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Archean peridotite
Mantle oxygen fugacity
North China craton
Plate subduction
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container_title Earth and planetary science letters
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Wang, Chao
Allen, Mark B.
Tang, Ming
Chen, Yi
Jia, Lihui
Song, Shuguang
description •Oxygen fugacity of neoarchean subduction-metasomatized peridotites is measured.•Neoarchean subduction zone mantle in the North China Craton was oxidized.•Neoarchean rise of mantle oxidation in the North China Craton was caused by plate subduction. The Archean mantle redox state played an important role in degassing of the Earth's interior and thus influenced atmospheric oxygen levels of the early Earth. But it is unclear if any parts of the uppermost mantle were significantly oxidized by a certain point in the Archean. Here, we investigate oxygen fugacity (fO2) of Archean (> 2535–2517 Ma) peridotites in the North China Craton. Petrology and geochemistry reveal that they experienced strong Neoarchean subduction-related metasomatism. These Neoarchean subduction-metasomatized peridotites record fO2 of ΔFMQ +1.3 ± 0.4 (SD) [relative to the fayalite-magnetite-quartz (FMQ) buffer], which are more oxidized than the Archean ambient mantle, but similar to the modern sub-arc mantle. We propose that this Neoarchean rise of mantle oxidation in the North China Craton was induced by plate subduction, during which the Neoarchean sub-arc mantle in the North China Craton could have been metasomatized and oxidized, and its oxygen fugacity was increased. This process may have had connections with the Great Oxidation Event in the Early Proterozoic.
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The Archean mantle redox state played an important role in degassing of the Earth's interior and thus influenced atmospheric oxygen levels of the early Earth. But it is unclear if any parts of the uppermost mantle were significantly oxidized by a certain point in the Archean. Here, we investigate oxygen fugacity (fO2) of Archean (&gt; 2535–2517 Ma) peridotites in the North China Craton. Petrology and geochemistry reveal that they experienced strong Neoarchean subduction-related metasomatism. These Neoarchean subduction-metasomatized peridotites record fO2 of ΔFMQ +1.3 ± 0.4 (SD) [relative to the fayalite-magnetite-quartz (FMQ) buffer], which are more oxidized than the Archean ambient mantle, but similar to the modern sub-arc mantle. 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subjects Archean peridotite
Mantle oxygen fugacity
North China craton
Plate subduction
title Rise of mantle oxidation by Neoarchean subduction in the North China Craton
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