A low accretion efficiency of planetesimals formed at planetary gap edges

TL;DR

This study uses N-body simulations to show that planetesimal accretion at planetary gap edges is inefficient, challenging the idea that late heavy element enrichment in giant planets is due to planetesimal accretion.

Contribution

The paper demonstrates through simulations that planetesimal accretion at gap edges is too low to explain giant planet heavy element content, suggesting alternative enrichment processes.

Findings

Accretion efficiency of planetesimals at gap edges is less than 10%.

Accretion becomes negligible when planetesimals form beyond the feeding zone.

Increased planetary migration enhances accretion efficiency.

Abstract

Observations and models of giant planets indicate that such objects are enriched in heavy elements compared to solar abundances. The prevailing view is that giant planets accreted multiple Earth masses of heavy elements after the end of core formation. Such late solid enrichment is commonly explained by the accretion of planetesimals. Planetesimals are expected to form at the edges of planetary gaps, and here we address the question of whether these planetesimals can be accreted in large enough amounts to explain the inferred high heavy element contents of giant planets. We perform a series of N-body simulations of the dynamics of planetesimals and planets during the planetary growth phase, taking into account gas drag as well as the enhanced collision cross-section caused by the extended envelopes. We consider the growth of Jupiter and Saturn via gas accretion after reaching the pebble isolation mass and we include their migration in an evolving disk. We find that the accretion efficiency of planetesimals formed at planetary gap edges is very low: less than 10% of the formed planetesimals are accreted even in the most favorable cases, which in our model corresponds to a few Earth-masses. When planetesimals are assumed to form beyond the feeding zone of the planets, extending to a few Hill radii from a planet, accretion becomes negligible. Furthermore, we find that the accretion efficiency increases when the planetary migration distance is increased and that the efficiency does not increase when the planetesimal radii are decreased. Based on these results we conclude that it is difficult to explain the large heavy element content of giant planets with planetesimal accretion during the gas accretion phase. Alternative processes most likely are required, e.g. accretion of vapor deposited by drifting pebbles.