Metasomatic fluids are thought to be oxidising agents that react with the surrounding mantle rocks, causing changes in the bulk Fe3+/ΣFe, their redox state, and affecting the partitioning of trace elements and the fractionation of O isotopes. Worldwide distributed metasomatized peridotites represent the ideal case study to investigate the role that crystal chemistry has on the O-isotope fractionation. We present mineral-chemical data of mantle peridotites from Tallante (Spain) such as major and trace elements, oxygen fugacity, and O-isotope data. Our results show that the O-isotope composition of volumetrically minor spinel in the residual mantle can be significantly affected by the oxidising metasomatic melts or fluids, likely implying that the oxidation of Fe2+ to Fe3+ favours 18O uptake in spinel structure with respect to 16O.
Fe Oxidation State and Oxygen Isotope Composition of Diverse Metasomatized Peridotite Rocks / Benedetti, Federica; Marras, Giulia; Cannaò, Enrico; Bianchini, Gianluca; Brunelli, Daniele; Dallai, Luigi; Stagno, Vincenzo. - In: TERRA NOVA. - ISSN 0954-4879. - accepted 1 July 2025(2025). [10.1111/ter.70001]
Fe Oxidation State and Oxygen Isotope Composition of Diverse Metasomatized Peridotite Rocks
Benedetti, Federica;Marras, Giulia;Dallai, Luigi
;Stagno, Vincenzo
2025
Abstract
Metasomatic fluids are thought to be oxidising agents that react with the surrounding mantle rocks, causing changes in the bulk Fe3+/ΣFe, their redox state, and affecting the partitioning of trace elements and the fractionation of O isotopes. Worldwide distributed metasomatized peridotites represent the ideal case study to investigate the role that crystal chemistry has on the O-isotope fractionation. We present mineral-chemical data of mantle peridotites from Tallante (Spain) such as major and trace elements, oxygen fugacity, and O-isotope data. Our results show that the O-isotope composition of volumetrically minor spinel in the residual mantle can be significantly affected by the oxidising metasomatic melts or fluids, likely implying that the oxidation of Fe2+ to Fe3+ favours 18O uptake in spinel structure with respect to 16O.| File | Dimensione | Formato | |
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