Evidence that Core-Powered Mass-Loss Dominates Over Photoevaporation in Shaping the Kepler Radius Valley

Abstract

The dearth of planets with sizes around 1.8 R is a key demographic feature discovered by the Kepler mission. Two theories have emerged as potential explanations for this valley: photoevaporation and core-powered mass-loss. However, Rogers et al. (2021) shows that differentiating between the two theories is possible using the three-dimensional parameter space of planet radius, incident flux, and stellar mass. We use homogeneously-derived stellar and planetary parameters to measure the Kepler exoplanet radius gap in this three-dimensional space. We compute the slope of the gap as a function of incident flux at constant stellar mass (α (∂ Rgap / ∂ S )M) and the slope of the gap as a function of stellar mass at constant incident flux (β (∂ Rgap / ∂ M )S) and find α = 0.069+0.019-0.023 and β = -0.046+0.125-0.117. Given that Rogers et al. (2021) shows that core-powered mass-loss predicts α ≈ 0.08 and β ≈ 0.00 while photoevaporation predicts α ≈ 0.12 and β ≈ --0.17, our measurements are more consistent with core-powered mass-loss than photoevaporation. However, we caution that different gap-determination methods can produce systematic offsets in both α and β; therefore, we motivate a comprehensive re-analysis of Kepler light curves with modern, updated priors on eccentricity and mean stellar density to improve both the accuracy and precision of planet radii and subsequent measurements of the gap.