Evidence for Two Hot Jupiter Formation Paths
Abstract
Disk migration and high-eccentricity migration are two well-studied theories to explain the formation of hot Jupiters. The former predicts that these planets can migrate up until the planet-star Roche separation () and the latter predicts they will tidally circularize at a minimum distance of 2. Considering long-running radial velocity and transit surveys have identified a couple hundred hot Jupiters to date, we can revisit the classic question of hot Jupiter formation in a data-driven manner. We approach this problem using data from several exoplanet surveys (radial velocity, Kepler, HAT, and WASP) allowing for either a single population or a mixture of populations associated with these formation channels, and applying a hierarchical Bayesian mixture model of truncated power laws of the form to constrain the population-level parameters of interest (e.g., location of inner edges, , mixture fractions). Within the limitations of our chosen models, we find the current radial velocity and Kepler sample of hot Jupiters can be well explained with a single truncated power law distribution with a lower cutoff near 2, a result that still holds after a decade, and . However, the HAT and WASP data show evidence for multiple populations (Bayes factor ). We find that reside in a component consistent with disk migration () and in one consistent with high-eccentricity migration (). We find no immediately strong connections with some observed host star properties and speculate on how future exoplanet surveys could improve upon hot Jupiter population inference.
Cite
@article{arxiv.1703.09711,
title = {Evidence for Two Hot Jupiter Formation Paths},
author = {Benjamin E. Nelson and Eric B. Ford and Frederic A. Rasio},
journal= {arXiv preprint arXiv:1703.09711},
year = {2017}
}
Comments
15 pages, 7 figures, 1 table. Submitted to AJ. The full analysis is publicly available at https://github.com/benelson/hjs_with_stan/