High-temperature water–olivine interaction and hydrogen liberation  in the subarc mantle

Oxidized fluids in the subduction zone may convert polyvalent elements in the mantle to their higher valence states. The most abundant polyvalent element in the mantle is Fe, a significant part of which is contained in olivine as Fe 2+ . Results of the study of arc mantle xenoliths, in lab high-pres...

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Bibliographic Details
Published in:Contributions to mineralogy and petrology 2022-04, Vol.177 (4), Article 47
Main Authors: Zelenski, Michael, Plyasunov, Andrey V., Kamenetsky, Vadim S., Nekrylov, Nikolay, Matveev, Danila, Korneeva, Alina
Format: Article
Language:English
Subjects:
Earth and Environmental Science
Earth Sciences
Fluids
Geology
High temperature
High temperature effects
Hydrogen
Inclusions
Iron
Magnesium
Mineral Resources
Mineralogy
Moisture content
Olivine
Original Paper
Oxidation
Petrology
Reaction products
Rocks, Igneous
Serpentine
Serpentinization
Silica
Silicon dioxide
Spinel
Spinel group
Subduction
Subduction (geology)
Subduction zones
Temperature
Thermodynamic models
Valence
Water content
Water temperature
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Summary:Oxidized fluids in the subduction zone may convert polyvalent elements in the mantle to their higher valence states. The most abundant polyvalent element in the mantle is Fe, a significant part of which is contained in olivine as Fe 2+ . Results of the study of arc mantle xenoliths, in lab high-pressure–high-temperature experiments, and thermodynamic modeling have shown that at pressures of ~ 50–2000 MPa and temperatures of 1000–1250 °C, well above the serpentine stability field, Fe 2+ from olivine reacts with free aqueous fluid according to the following simplified reaction: 3Fe 2 SiO 4  + 2H 2 O ⇆ 3SiO 2  + 2Fe 3 O 4  + 2H 2 . The resulting ferric iron is preserved in spinel of a certain composition, Mg,Fe 2 + Fe 2 3 + O 4 , whereas new high-Mg olivine, with magnesium number up to 96 in natural samples and 99.9 in experiments, forms in the reaction zone. SiO 2 produced in the reaction either dissolves in the fluid or, with a small amount of water, reacts with olivine to form orthopyroxene as follows: (Mg,Fe) 2 SiO 4  + SiO 2  = (Mg,Fe) 2 Si 2 O 6 . The released H 2 may decrease the oxidation state of polyvalent elements present in the fluid (e.g., S 4+ , S 6+ ). Traces of high-temperature water–olivine interaction appear as swarms of fluid-spinel inclusions and are ubiquitous in olivine from ultramafic arc xenoliths. The described process is similar to serpentinization but occurs at higher pressure and temperature conditions and yields different reaction products. The reducing capacity of olivine is relatively low; however, given the large volume of mantle (and crustal) peridotites, the overall effect may be significant.
ISSN:0010-7999
1432-0967
DOI:10.1007/s00410-022-01910-z