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Compositions of carbonaceous-type asteroidal cores in the early solar system

Bidong Zhang, N. L. Chabot, Alan E. Rubin

2022Science Advances24 citationsDOIOpen Access PDF

Abstract

The parent cores of iron meteorites belong to the earliest accreted bodies in the solar system. These cores formed in two isotopically distinct reservoirs: noncarbonaceous (NC) type and carbonaceous (CC) type in the inner and outer solar system, respectively. We measured elemental compositions of CC-iron groups and used fractional crystallization modeling to reconstruct the bulk compositions and crystallization processes of their parent asteroidal cores. We found generally lower S and higher P in CC-iron cores than in NC-iron cores and higher HSE (highly siderophile element) abundances in some CC-iron cores than in NC-iron cores. We suggest that the different HSE abundances among the CC-iron cores are related to the spatial distribution of refractory metal nugget-bearing calcium aluminum-rich inclusions (CAIs) in the protoplanetary disk. CAIs may have been transported to the outer solar system and distributed heterogeneously within the first million years of solar system history.

Topics & Concepts

Solar SystemMeteoriteParent bodyFormation and evolution of the Solar SystemAstrobiologyCrystallizationProtoplanetary diskChondriteCarbonaceous chondriteFractional crystallization (geology)GeologyGeochemistryMineralogyChemistryPlanetAstrophysicsBasaltPhysicsOrganic chemistryAstro and Planetary SciencePlanetary Science and ExplorationGeological and Geochemical Analysis
Compositions of carbonaceous-type asteroidal cores in the early solar system | Litcius