The Bimodal Distribution in Exoplanet Radii: Considering Varying Core Compositions and H2 Envelope's Sizes

Abstract

Several models have been introduced in order to explain the radius distribution in exoplanet radii observed by Fulton et al. (2017) with one peak at 1.3 R the other at 2.4 R and the minimum at 1.75R . In this paper we focus on the hypothesis that the exoplanet size distribution is caused by stellar XUV-induced atmospheric loss. We evolve 106 synthetic exoplanets by exposing them to XUV irradiation from synthetic ZAMS stars. For each planet we set a different interior composition which ranged from 100 \: wt\% Fe (very dense) through 100 \: wt\% MgSiO3 (average density) and to 100 \: wt\% H2O ice (low density) with varying hydrogen envelop sizes which varied from 0 \: wt\% (a negligible envelop) to 100 \: wt\% (a negligible core). Our simulations were able to replicate the bimodal distribution in exoplanet radii. We argue that in order to reproduce the distribution by Fulton et al. (2017) it is mandatory for there to be a paucity of exoplanets with masses above 8M. Furthermore, our best-fit result predicts an initial flat distribution in exoplanet occurrence for MP 8M with a strong deficiency for planets with 3M. Our results are consistent with the 1.3R radius peak mostly encompassing denuded exoplanets whilst the 2.4R radius peak mainly comprising exoplanets with large hydrogen envelops