The Sun’s Birth Environment: Context for Meteoritics

Meteorites trace planet formation in the Sun’s protoplanetary disk, but they also record the influence of the Sun’s birth environment. Whether the Sun formed in a region like Taurus-Auriga with ∼ 10 2 stars, or a region like the Carina Nebula with ∼ 10 6 stars, matters for how large the Sun’s disk w...

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Bibliographic Details
Published in:Space science reviews 2024-10, Vol.220 (7), p.76, Article 76
Main Authors: Desch, Steve, Miret-Roig, Núria
Format: Article
Language:English
Subjects:
Aerospace Technology and Astronautics
Astrochemistry
Astrophysics and Astroparticles
Context
Data acquisition
Gases
Jupiter
Jupiter atmosphere
Kuiper belt
Molecular clouds
Orion nebula
Physics
Physics and Astronomy
Planet formation
Planetology
Pluto
Protoplanetary disks
Radioisotopes
Rare gases
Solar system
Space Exploration and Astronautics
Space Sciences (including Extraterrestrial Physics
Star formation
Stars
Trans-Neptunian objects
Wolf-Rayet stars
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Summary:Meteorites trace planet formation in the Sun’s protoplanetary disk, but they also record the influence of the Sun’s birth environment. Whether the Sun formed in a region like Taurus-Auriga with ∼ 10 2 stars, or a region like the Carina Nebula with ∼ 10 6 stars, matters for how large the Sun’s disk was, for how long and from how far away it accreted gas from the molecular cloud, and how it acquired radionuclides like 26 Al. To provide context for the interpretation of meteoritic data, we review what is known about the Sun’s birth environment. Based on an inferred gas disk outer radius ≈ 50 − 90 AU, radial transport in the disk, and the abundances of noble gases in Jupiter’s atmosphere, the Sun’s molecular cloud and protoplanetary disk were exposed to an ultraviolet flux G 0 ∼ 30 − 3000 during its birth and first ≈ 10 Myr of evolution. Based on the orbits of Kuiper Belt objects, the Solar System was subsequently exposed to a stellar density ≈ 100 M ⊙ pc − 3 for ≈ 100 Myr, strongly implying formation in a bound cluster. These facts suggest formation in a region like the outskirts of the Orion Nebula, perhaps 2 pc from the center. The protoplanetary disk might have accreted gas for many Myr, but a few × 10 5 yr seems more likely. It probably inherited radionuclides from its molecular cloud, enriched by inputs from supernovae and especially Wolf-Rayet star winds, and acquired a typical amount of 26 Al.
ISSN:0038-6308
1572-9672
DOI:10.1007/s11214-024-01113-x