English

Terrestrial planet formation from a ring

Earth and Planetary Astrophysics 2023-03-10 v1

Abstract

It has been long proposed that, if all the terrestrial planets form within a tiny ring of solid material at around 1 AU, the concentrated mass-distance distribution of the current system can be reproduced. Recent planetesimal formation models also support this idea. In this study, we revisit the ring model by performing a number of high-resolution N-body simulations for 10 Myr of a ring of self-interacting planetesimals, with various radial distributions of the gas disc. We found that even if all the planetesimals form at ~1 AU in a minimum mass solar nebula-like disc, the system tends to spread radially as accretion proceeds, resulting in a system of planetary embryos lacking mass-concentration at ~1 AU. Modifying the surface density of the gas disc into a concave shape with a peak at ~1 AU helps to maintain mass concentrated at ~1 AU and solve the radial dispersion problem. We further propose that such a disc should be short lived (<= 1 Myr) and with a shallower radial gradient in the innermost region (< 1 AU) than previously proposed to prevent a too-rapid growth of Earth. Future studies should extend to ~100 Myr the most promising simulations and address in a self-consistent manner the evolution of the asteroid belt and its role in the formation of the terrestrial planets.

Keywords

Cite

@article{arxiv.2302.14100,
  title  = {Terrestrial planet formation from a ring},
  author = {J. M. Y. Woo and A. Morbidelli and S. L. Grimm and J. Stadel and R. Brasser},
  journal= {arXiv preprint arXiv:2302.14100},
  year   = {2023}
}

Comments

Accepted by Icarus

R2 v1 2026-06-28T08:51:02.736Z