Identifying the "true" radius of the hot sub-Neptune CoRoT-24b by mass loss modelling

Abstract

For the hot exoplanets CoRoT-24b and CoRoT-24c, observations have provided transit radii R T of 3.70.4 R and 4.90.5 R, and masses of 5.7 M and 2811 M, respectively. We study their upper atmosphere structure and escape applying an hydrodynamic model. Assuming R T ≈ R PL, where R PL is the planetary radius at the pressure of 100 mbar, we obtained for CoRoT-24b unrealistically high thermally-driven hydrodynamic escape rates. This is due to the planet's high temperature and low gravity, independent of the stellar EUV flux. Such high escape rates could last only for <100 Myr, while R PL shrinks till the escape rate becomes less than or equal to the maximum possible EUV-driven escape rate. For CoRoT-24b, R PL must be therefore located at ≈ 1.9-2.2 R and high altitude hazes/clouds possibly extinct the light at R T. Our analysis constraints also the planet's mass to be 5-5.7 M. For CoRoT-24c, R PL and R T lie too close together to be distinguished in the same way. Similar differences between R PL and R T may be present also for other hot, low-density sub-Neptunes.