An Analysis of the Radius Gap in a Sample of Kepler, K2 and TESS exoplanets orbiting M Dwarf Stars

Abstract

Planetary radii are derived for 218 exoplanets orbiting 161 M dwarf stars. Stellar radii are based on an analysis of APOGEE high-resolution near-IR spectra for a subsample of the M-dwarfs; these results are used to define a stellar radius-M K s calibration that is applied to the sample of M-dwarf planet hosts. The planetary radius distribution displays a gap over R p1.6-2.0 R, bordered by two peaks at R p1.2-1.6 R (super-Earths) and 2.0-2.4 R (sub-Neptunes). The radius gap is nearly constant with exoplanetary orbital period (a power-law slope of m=+0.01+0.03-0.04), which is different (2-3σ) from m-0.10 found previously for FGK dwarfs. This flat slope agrees with pebble accretion models, which include photoevaporation and inward orbital migration. The radius gap as a function of insolation is approximately constant over the range of S p20-250 S. The R p-P orb plane exhibits a sub-Neptune desert for P orb<2d, that appears at S p>120 S, being significantly smaller than S p>650 S found in the FGK planet-hosts, indicating that the appearance of the sub-Neptune desert is a function of host-star mass. Published masses for 51 exoplanets are combined with our radii to determine densities, which exhibit a gap at p0.9, separating rocky exoplanets from sub-Neptunes. The density distribution within the sub-Neptune family itself reveals two peaks, at p0.4 and 0.7. Comparisons to planetary models find that the low-density group are gas-rich sub-Neptunes, while the group at < p>0.7 likely consists of volatile-rich water worlds.