# Pebble accretion in self-gravitating protostellar discs

**Authors:** Duncan H Forgan

arXiv: 1902.05385 · 2019-03-06

## TL;DR

This paper investigates pebble accretion in massive, self-gravitating protostellar discs, revealing that typical conditions hinder streaming instability and core formation, emphasizing the need to understand solid body distribution in such environments.

## Contribution

It applies standard pebble accretion and streaming instability models to self-gravitating discs, highlighting challenges and potential pathways for planet formation in these conditions.

## Key findings

- Pebble-to-gas-density ratio generally below 0.01
- Streaming instability may activate with 10 cm grains in spiral structures
- Lunar mass cores could form in a few thousand years, but likely rarely

## Abstract

Pebble accretion has become a popular component to core accretion models of planet formation, and is especially relevant to the formation of compact, resonant terrestrial planetary systems. Pebbles initially form in the inner protoplanetary disc, sweeping outwards in a radially expanding front, potentially forming planetesimals and planetary cores via migration and the streaming instability. This pebble front appears at early times, in what is typically assumed to be a low mass disc. We argue this picture is in conflict with the reality of young circumstellar discs, which are massive and self-gravitating. We apply standard pebble accretion and streaming instability formulae to self-gravitating protostellar disc models. Fragments will open a gap in the pebble disc, but they will likely fail to open a gap in the gas, and continue rapid inward migration. If this does not strongly perturb the pebble disc, our results show that disc fragments will accrete pebbles efficiently. We find that in general the pebble-to-gas-density ratio fails to exceed 0.01, suggesting that the streaming instability will struggle to operate. It may be possible to activate the instability if 10 cm grains are available, and spiral structures can effectively concentrate them in regions of low gravito-turbulence. If this occurs, lunar mass cores might be assembled on timescales of a few thousand years, **but this is likely to be rare, and is far from proven**. In any case, this work highlights the need for study of how self-gravitating protostellar discs define the distribution and properties of solid bodies, for future planet formation by core accretion.

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/1902.05385/full.md

## References

86 references — full list in the complete paper: https://tomesphere.com/paper/1902.05385/full.md

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Source: https://tomesphere.com/paper/1902.05385