Litcius/Paper detail

Reconciling metal–silicate partitioning and late accretion in the Earth

Terry‐Ann Suer, Julien Siebert, Laurent Rémusat, James M.D. Day, Stephan Borensztajn, B. Doisneau, G. Fiquet

2021Nature Communications45 citationsDOIOpen Access PDF

Abstract

Abstract Highly siderophile elements (HSE), including platinum, provide powerful geochemical tools for studying planet formation. Late accretion of chondritic components to Earth after core formation has been invoked as the main source of mantle HSE. However, core formation could also have contributed to the mantle’s HSE content. Here we present measurements of platinum metal-silicate partitioning coefficients, obtained from laser-heated diamond anvil cell experiments, which demonstrate that platinum partitioning into metal is lower at high pressures and temperatures. Consequently, the mantle was likely enriched in platinum immediately following core-mantle differentiation. Core formation models that incorporate these results and simultaneously account for collateral geochemical constraints, lead to excess platinum in the mantle. A subsequent process such as iron exsolution or sulfide segregation is therefore required to remove excess platinum and to explain the mantle’s modern HSE signature. A vestige of this platinum-enriched mantle can potentially account for 186 Os-enriched ocean island basalt lavas.

Topics & Concepts

Mantle (geology)SilicatePlatinumPlanetary differentiationGeologyGeochemistryEarly EarthPlatinum groupBasaltPrimitive mantleAstrobiologyMineralogyChemistryPartial meltingMantle convectionSubductionTectonicsPhysicsPaleontologyCatalysisBiochemistryOrganic chemistryGeological and Geochemical AnalysisHigh-pressure geophysics and materialsAstro and Planetary Science