Combining Transit and RV: A Synthesized Population Model

Abstract

We present a framework for estimating exoplanet occurrence rates by synthesizing constraints from radial velocity and transit surveys simultaneously. We employ approximate Bayesian computation and various mass-radius (M-R) relations to explore the population models describing these surveys, both separately and in a joint fit. Using this approach, we fit a planet distribution function of the form d2 N/dPdM Pβ Mα, with a break in the power law in mass at Mb, to planets orbiting FGK stars with periods P = [25, 200] days and masses M = [2, 50] M. We find that the M-R relation from Otegi et al. (2020), which lets rocky and volatile-rich populations overlap in mass, allows us to find a model that is consistent with both types of surveys. Our joint fit gives Mb = 21.6-3.2+2.5 M (errors reflect 68.3% credible interval). This is nearly a factor of three higher than the break from transit-only considerations and an M-R relation without such an overlap. The corresponding planet-star mass ratio break qb 7×10-5 may be consistent with microlensing studies (qb 6×10-5 - 2×10-4). The joint fit also requires that a fraction of Frocky = 0.63-0.04+0.04 planets in the overlap region belong to the rocky population. Our results strongly suggest that future M-R relations should account for a mixture of distinct types of planets in order to describe the observed planet population.