Litcius/Paper detail

Hydrodynamic escape of mineral atmosphere from hot rocky exoplanet. I. Model description

Yūichi Itō, Masahiro Ikoma

2020Monthly Notices of the Royal Astronomical Society38 citationsDOIOpen Access PDF

Abstract

ABSTRACT Recent exoplanet statistics indicate that photo-evaporation has a great impact on the mass and bulk composition of close-in low-mass planets. While there are many studies addressing photo-evaporation of hydrogen- or water-rich atmospheres, no detailed investigation regarding rocky vapour atmospheres (or mineral atmospheres) has been conducted. Here, we develop a new 1D hydrodynamic model of the ultraviolet (UV)-irradiated mineral atmosphere composed of Na, Mg, O, Si, their ions and electrons, including molecular diffusion, thermal conduction, photo-/thermochemistry, X–ray and UV heating, and radiative line cooling (i.e. the effects of the optical thickness and non-local thermal equilibrium). The focus of this paper is on describing our methodology but presents some new findings. Our hydrodynamic simulations demonstrate that almost all of the incident X-ray and UV energy from the host star is converted into and lost by the radiative emission of the coolant gas species such as Na, Mg, Mg+, Si2+, Na3+, and Si3+. For an Earth-size planet orbiting 0.02 au around a young solar-type star, we find that the X-ray and UV heating efficiency is as small as 1 × 10−3, which corresponds to 0.3 M⊕ Gyr−1 of the mass-loss rate simply integrated over all the directions. Because of such efficient cooling, the photo-evaporation of the mineral atmosphere on hot rocky exoplanets with masses of 1 M⊕ is not massive enough to exert a great influence on the planetary mass and bulk composition. This suggests that close-in high-density exoplanets with sizes larger than the Earth radius survive in the high-UV environments.

Topics & Concepts

ExoplanetPlanetPhysicsAtmosphere (unit)AstrobiologyAstrophysicsRadiative transferGas giantEvaporationRadiative coolingAstronomyThermodynamicsQuantum mechanicsStellar, planetary, and galactic studiesAstrophysics and Star Formation StudiesAstro and Planetary Science