Hybrid accretion of carbonaceous chondrites by radial transport across the Jupiter barrier

TL;DR

This study reveals that chondrules and dust in carbonaceous chondrites underwent complex radial transport across the Jupiter barrier, indicating significant mixing in the early Solar System and challenging the idea of Jupiter as an effective barrier.

Contribution

It provides detailed isotopic evidence for radial transport of materials across Jupiter's orbit, suggesting a more dynamic early Solar System than previously thought.

Findings

Chondrules show an onion-shell structure with isotopic gradients.

Inner Solar System formation of chondrules with outward transport past Jupiter.

Limited effectiveness of Jupiter as a barrier to material exchange.

Abstract

Understanding the origin of chondritic components and their accretion pathways is critical to unravel the magnitude of mass transport in the protoplanetary disk, the accretionary history of the terrestrial planet region and, by extension, its prebiotic inventory. Here, we trace the heritage of pristine components from the relatively unaltered CV chondrite Leoville through their mass-independent Cr and mass-dependent Zn isotope compositions. Investigating these chondritic fractions in such detail reveals an onion-shell structure of chondrules, which is characterized by 54Cr- and 66Zn-poor cores surrounded by increasingly 54Cr- and 66Zn-rich igneous rims and an outer coating of fine-grained dust. This is interpreted as a progressive addition of 54Cr- and 66Zn-rich, CI-like material to the accretion region of these carbonaceous chondrites. Our findings show that the observed Cr isotopic range in chondrules from more altered CV chondrites is the result of chemical equilibration between chondrules and matrix during secondary alteration. The 54Cr-poor nature of the cores of Leoville chondrules implies formation in the inner Solar System and subsequent massive outward chondrule transport past the Jupiter barrier. At the same time, CI-like dust is transferred inwards. We propose that the accreting Earth acquired CI-like dust through this mechanism within the lifetime of the disk. This radial mixing of chondrules and matrix shows the limited capacity of Jupiter to act as an efficient barrier and maintain the proposed non-carbonaceous and carbonaceous chondrite dichotomy over time. Finally, also considering current astrophysical models, we explore both inner and outer Solar System origins for the CV chondrite parent body.