XUV exposed, non-hydrostatic hydrogen-rich upper atmospheres of terrestrial planets II: Hydrogen coronae and ion escape

TL;DR

This study models hydrogen-rich upper atmospheres of Earth-like and super-Earth planets under stellar wind and XUV flux, revealing ion production and escape processes crucial for understanding planetary atmospheric evolution.

Contribution

It provides a detailed modeling of hydrogen coronae and ion escape mechanisms for terrestrial planets in habitable zones under varying stellar conditions, including non-thermal escape estimates.

Findings

Ion production rates vary widely depending on stellar wind and XUV flux.

Most planetary ions are lost via stellar wind pickup.

Non-thermal escape is generally smaller than thermal escape over planetary lifetimes.

Abstract

We study the interactions between the stellar wind plasma flow of a typical M star, such as GJ 436, and hydrogen-rich upper atmospheres of an Earth-like planet and a "super-Earth" with the radius of 2 R_Earth and a mass of 10 M_Earth, located within the habitable zone at ~0.24 AU. We investigate the formation of extended atomic hydrogen coronae under the influences of the stellar XUV flux (soft X-rays and EUV), stellar wind density and velocity, shape of a planetary obstacle (e.g., magnetosphere, ionopause), and the loss of planetary pick-up ions on the evolution of hydrogen-dominated upper atmospheres. Stellar XUV fluxes which are 1, 10, 50 and 100 times higher compared to that of the present-day Sun are considered and the formation of high-energy neutral hydrogen clouds around the planets due to the charge-exchange reaction under various stellar conditions have been modeled. Charge-exchange between stellar wind protons with planetary hydrogen atoms, and photoionization, leads to the production of initially cold ions of planetary origin. We found that the ion production rates for the studied planets can vary over a wide range, from ~1.0x10^{25} s^{-1} to ~5.3x10^{30} s^{-1}, depending on the stellar wind conditions and the assumed XUV exposure of the upper atmosphere. Our findings indicate that most likely the majority of these planetary ions are picked up by the stellar wind and lost from the planet. Finally, we estimate the long-time non-thermal ion pick-up escape for the studied planets and compare them with the thermal escape. According to our estimates, non-thermal escape of picked up ionized hydrogen atoms over a planet's lifetime varies between ~0.4 Earth ocean equivalent amounts of hydrogen (EO_H) to <3 EO_H and usually is several times smaller in comparison to the thermal atmospheric escape rates.