TL;DR
This paper models early Solar System planet formation, incorporating planetesimal and pebble accretion in an evolving disk, to match observed planetary characteristics and constrain uncertain aspects of the process.
Contribution
It introduces a comprehensive model including disk winds and accretion processes, providing new insights into planet formation regions and growth limitations.
Findings
Pebble accretion dominates beyond the ice line.
Planetesimal accretion is more significant inside the ice line.
Mars-sized objects can form inside the ice line with planetesimal accretion.
Abstract
We model the early stages of planet formation in the Solar System, including continual planetesimal formation, and planetesimal and pebble accretion onto planetary embryos in an evolving disk driven by a disk wind. The aim is to constrain aspects of planet formation that have large uncertainties by matching key characteristics of the Solar System. The model produces a good fit to these characteristics for a narrow range of parameter space. Planetary growth beyond the ice line is dominated by pebble accretion. Planetesimal accretion is more important inside the ice line. Pebble accretion inside the ice line is slowed by higher temperatures, partial removal of inflowing pebbles by planetesimal formation and pebble accretion further out in the disk, and increased radial velocities due to gas advection. The terrestrial planets are prevented from accreting much water ice because embryos…
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Taxonomy
TopicsAstro and Planetary Science · Planetary Science and Exploration · Space Exploration and Technology