Rocky planet formation in compact disks around M dwarfs

TL;DR

This study uses N-body simulations to explore how rocky planets form around M dwarfs in compact disks, emphasizing the role of pebble accretion and disk viscosity in reproducing observed exoplanet populations.

Contribution

It demonstrates that low-viscosity gas disks facilitate the formation of close-in rocky planets via pebble accretion, aligning with observed exoplanet characteristics.

Findings

Low-viscosity disks ($\alpha=10^{-4}$) reproduce observed planet populations.

High-viscosity disks ($\alpha=10^{-3}$) fail to match observed planet masses.

Planetesimal accretion tends to produce smaller planets than pebble accretion.

Abstract

Rocky planets in compact configurations are the most common ones around M dwarfs. Many disks around very low mass stars (between 0.1 and 0.5 M$_\odot$) are rather compact and small (without observable substructures and radius less than 20 au), which favours the idea of an efficient radial drift that could enhance planet formation in compact orbits. We aim to investigate the potential formation paths of the observed close-in rocky exoplanet population around M dwarfs, assuming that planet formation could take place in compact disks with an efficient dust radial drift. We developed N-body simulations that include a sample of embryos growing by pebble accretion exposed to planet-disk interactions, star-planet tidal interactions and general relativistic corrections. For a star of 0.1 M$_\odot$ we considered different gas disk viscosity and initial embryo distributions. We also explore planet formation by pebble accretion around stars of 0.3 and 0.5 M$_\odot$. Lastly, for each stellar mass, we run simulations that include a sample of embryos growing by planetesimal accretion. Our main result is that the sample of simulated planets that grow by pebble accretion in a gas disk with low viscosity ($\alpha=10^{-4}$) can reproduce the close-in low-mass exoplanet population around M dwarfs in terms of multiplicity, masses and semi-major axis. Furthermore, we found that a gas disk with high viscosity ($\alpha=10^{-3}$) can not reproduce the observed planet masses. Also, we show that planetesimal accretion favours the formation of smaller planets than the ones formed by pebble accretion. Rocky planet formation around M dwarfs can take place in compact and small dust disks driven by an efficient radial drift in a gas disk with low viscosity. This result points towards a new approach in the direction of the disk conditions needed for rocky planet formation around very low mass stars.