English

Atmospheric Evolution on Low-gravity Waterworlds

Earth and Planetary Astrophysics 2019-08-15 v2

Abstract

Low-gravity waterworlds (M0.1MM\lesssim 0.1 M_{\oplus}) are of interest for their potential habitability. The weakly bound atmospheres of such worlds have proportionally larger radiative surfaces and are more susceptible to escape. We conduct a unified investigation into these phenomena, combining analytical energy balance and hydrodynamic escape with line-by-line radiative transfer calculations. Because outgoing radiation is forced to increase with surface temperature by the expansion of the radiative surface, we find that these worlds do not experience a runaway greenhouse. Furthermore, we show that a long-lived liquid water habitable zone is possible for low-gravity waterworlds of sufficient mass. Its inner edge is set by the rate of atmospheric escape, because a short-lived atmosphere limits the time available for life to evolve. In describing the physics of the parameter space transition from "planet-like" to "comet-like", our model produces a lower bound for habitability in terms of gravity. These results provide valuable insights in the context of the ongoing hunt for habitable exoplanets and exomoons.

Keywords

Cite

@article{arxiv.1906.10561,
  title  = {Atmospheric Evolution on Low-gravity Waterworlds},
  author = {Constantin W. Arnscheidt and Robin D. Wordsworth and Feng Ding},
  journal= {arXiv preprint arXiv:1906.10561},
  year   = {2019}
}

Comments

published in ApJ; text updated to match published version

R2 v1 2026-06-23T10:03:09.403Z