Orbital Evolution of Close-in Super-Earths Driven by Atmospheric Escape

TL;DR

This study models how atmospheric escape causes outward orbital migration of close-in super-Earths, influencing their distribution and features like the radius gap and Neptune desert, especially around different star types.

Contribution

It presents a new calculation of orbital evolution of evaporating super-Earths considering angular momentum changes, explaining observed planetary features and distributions.

Findings

Orbital radius increases proportionally with atmospheric mass loss during high stellar XUV phases.

Super-Earths around G- and M-type stars tend to migrate outward due to atmospheric escape.

The observed radius gap and Neptune desert are reproduced in simulations, especially around FGK stars.

Abstract

The increasing number of super-Earths close to their host stars revealed a scarcity of close-in small planets with 1.5-2.0$\,R_\oplus$ in the radius distribution of ${\it Kepler}$ planets. The atmospheric escape of super-Earths by photoevaporation can explain the origin of the observed "radius gap." Many theoretical studies considered the in-situ mass loss of a close-in planet. Planets that undergo the atmospheric escape, however, move outward due to the change in the orbital angular momentum of their star-planet systems. In this study, we calculate the orbital evolution of an evaporating super-Earth with a H$_2$/He atmosphere around FGKM-type stars under a stellar X-ray and extreme UV irradiation (XUV). The rate of increase in the orbital radius of an evaporating planet is approximately proportional to that of the atmospheric mass loss during a high stellar XUV phase. We show that super-Earths with a rocky core of $\lesssim$ 10$\,M_\oplus$ and a H$_2$/He atmosphere at $\lesssim$ 0.03-0.1$\,$au ($\lesssim$ 0.01-0.03$\,$au) around G-type stars (M-type stars) are prone to the outward migration driven by photoevaporation. Although the changes in the orbits of the planets would be small, they would rearrange the orbital configurations of compact, multi-planet systems, such as the TRAPPIST-1 system. We also find that the radius gap and the so-called "Neptune desert" in the observed population of close-in planets around FGK-type stars still appear in our simulations. On the other hand, the observed planet population around M-type stars can be reproduced only by a high stellar XUV luminosity model.