Nucleosynthetic isotope anomalies of planetary materials provide insight into their genetic
ties, informing our understanding of early Solar System isotopic architecture and evolution …

Understanding the formation of our planetary system requires identification of the materials
from which it originated and the accretion processes that produced the planets. The …

Nucleosynthetic isotope signatures in meteorites provide key insights into the structure and
dynamics of the solar protoplanetary disk and the accretion history of the planets. We …

Isotope anomalies among planetary bodies provide key constraints on planetary genetics
and the solar system's dynamical evolution. However, to unlock the full potential of these …

The recent advent of nontraditional isotopic systems has revealed that meteorites display a
fundamental isotopic dichotomy between noncarbonaceous (NC) and carbonaceous (C) …

The elemental and isotopic compositions of meteorites are expected to reflect several key
processes that occurred in the early solar system, including the migration of gas and dust …

Nucleosynthetic isotope variations are powerful tools to investigate genetic relationships
between meteorite groups and planets. They are instrumental to assess the early evolution …

As the earliest dated solids, calcium–aluminum-rich inclusions (CAIs) provide a unique
window into the early solar system. However, for many elements, CAIs have been shown to …

The isotopic dichotomy between non-carbonaceous (NC) and carbonaceous (CC)
meteorites indicates that meteorite parent bodies derive from two genetically distinct …

The isotopic composition of meteorites reveals a fundamental dichotomy between non-
carbonaceous (NC) and carbonaceous (CC) meteorites. However, the origin of this …