Abstract
The isotopic dichotomy between non-carbonaceous (NC) and carbonaceous (CC) meteorites indicates that meteorite parent bodies derive from two genetically distinct reservoirs, which presumably were located inside (NC) and outside (CC) the orbit of Jupiter and remained isolated from each other for the first few million years of the solar system. Here we review the discovery of the NC–CC dichotomy and its implications for understanding the early history of the solar system, including the formation of Jupiter, the dynamics of terrestrial planet formation, and the origin and nature of Earth’s building blocks. The isotopic difference between the NC and CC reservoirs is probably inherited from the solar system’s parental molecular cloud and has been maintained through the rapid formation of Jupiter that prevented significant exchange of material from inside (NC) and outside (CC) its orbit. The growth and/or migration of Jupiter resulted in inward scattering of CC bodies, which accounts for the co-occurrence of NC and CC bodies in the present-day asteroid belt and the delivery of presumably volatile-rich CC bodies to the growing terrestrial planets. Earth’s primitive mantle, at least for siderophile elements like Mo, has a mixed NC–CC composition, indicating that Earth accreted CC bodies during the final stages of its growth, perhaps through the Moon-forming giant impactor. The late-stage accretion of CC bodies to Earth is sufficient to account for the entire budget of Earth’s water and highly volatile species.
Highlights
Most meteorites are fragments of asteroids located between Mars and Jupiter
These models are remarkably consistent with the isotopic dichotomy observed among meteorites, and collectively these studies indicate that S-type asteroids and NC meteorites represent inner solar system material, whereas C-type asteroids and CC meteorites derive from the outer solar system
The discovery of an isotopic dichotomy between non-carbonaceous (NC) and carbonaceous (CC) meteorites has fundamentally changed our understanding of early solar system evolution, including the origin of meteorites and how they can be used to constrain the dynamical evolution of the early solar system, and the formation of terrestrial planets
Summary
It has traditionally been thought that these bodies formed close to their present-day location, but this view was challenged recently by the discovery of an isotopic dichotomy between noncarbonaceous (NC) and carbonaceous (CC) meteorites (Budde et al 2016; Warren 2011) These two suites of meteorites derive from distinct reservoirs within the solar protoplanetary disk that remained spatially separated for several million years (Ma), most likely through the presence of Jupiter in between them (Kruijer et al 2017). Later work showed that planetesimals from beyond Jupiter may have been implanted into the asteroid belt during the growth of the giant planets, without the need to invoke a specific planetary migration pattern (Raymond and Izidoro 2017) These models are remarkably consistent with the isotopic dichotomy observed among meteorites, and collectively these studies indicate that S-type asteroids and NC meteorites represent inner solar system material, whereas C-type asteroids and CC meteorites derive from the outer solar system. The purpose of this paper is to review the meteorite dichotomy and its origin, and discuss its implications for understanding the early evolution of the solar accretion disk, the role of Jupiter in the early solar system, the formation of planetesimals, and the accretion history and building blocks of the terrestrial planets
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