TY - JOUR
T1 - The nucleosynthetic fingerprint of the outermost protoplanetary disk and early Solar System dynamics
AU - van Kooten, Elishevah
AU - Zhao, Xuchao
AU - Franchi, Ian
AU - Tung, Po-Yen
AU - Fairclough, Simon
AU - Walmsley, John
AU - Onyett, Isaac
AU - Schiller, Martin
AU - Bizzarro, Martin
N1 - Publisher Copyright:
© 2024 the Authors, some rights reserved;
PY - 2024
Y1 - 2024
N2 - Knowledge of the nucleosynthetic isotope composition of the outermost protoplanetary disk is critical to understand the formation and early dynamical evolution of the Solar System. We report the discovery of outer disk material preserved in a pristine meteorite based on its chemical composition, organic-rich petrology, and 15N-rich, deuterium-rich, and 16O-poor isotope signatures. We infer that this outer disk material originated in the comet-forming region. The nucleosynthetic Fe, Mg, Si, and Cr compositions of this material reveal that, contrary to current belief, the isotope signature of the comet-forming region is ubiquitous among outer Solar System bodies, possibly reflecting an important planetary building block in the outer Solar System. This nucleosynthetic component represents fresh material added to the outer disk by late accretion streamers connected to the ambient molecular cloud. Our results show that most Solar System carbonaceous asteroids accreted material from the comet-forming region, a signature lacking in the terrestrial planet region.
AB - Knowledge of the nucleosynthetic isotope composition of the outermost protoplanetary disk is critical to understand the formation and early dynamical evolution of the Solar System. We report the discovery of outer disk material preserved in a pristine meteorite based on its chemical composition, organic-rich petrology, and 15N-rich, deuterium-rich, and 16O-poor isotope signatures. We infer that this outer disk material originated in the comet-forming region. The nucleosynthetic Fe, Mg, Si, and Cr compositions of this material reveal that, contrary to current belief, the isotope signature of the comet-forming region is ubiquitous among outer Solar System bodies, possibly reflecting an important planetary building block in the outer Solar System. This nucleosynthetic component represents fresh material added to the outer disk by late accretion streamers connected to the ambient molecular cloud. Our results show that most Solar System carbonaceous asteroids accreted material from the comet-forming region, a signature lacking in the terrestrial planet region.
U2 - 10.1126/sciadv.adp1613
DO - 10.1126/sciadv.adp1613
M3 - Journal article
C2 - 38875339
AN - SCOPUS:85196239938
VL - 10
JO - Science advances
JF - Science advances
SN - 2375-2548
IS - 24
M1 - eadp1613
ER -