The Transition from Giant Planets to Brown Dwarfs beyond 1 au from the Stellar Metallicity Distribution
Abstract
Giant planets and brown dwarfs are thought to form via a combination of pathways, including bottom-up mechanisms in which gas is accreted onto a solid core and top-down mechanisms in which gas collapses directly into a gravitationally-bound object. One can distinguish the prevalence of these mechanisms using host star metallicities. Bottom-up formation thrives in metal-rich environments, whereas top-down formation is weakly dependent on ambient metal content. Using a hierarchical Bayesian model and the results of the California Legacy Survey (CLS), a low-bias and homogeneously analyzed radial velocity survey, we find evidence for a transition in the stellar metallicity distribution at a companion mass of γ = 27-8+12 \, M Jup for companions with orbital separations between 1-50 au. Companions below and above this threshold tend to orbit stars with higher ([Fe/H] = 0.17 0.12 dex) and lower ([Fe/H] = -0.03 0.10 dex) metallicities, respectively. Previous studies of relatively close-in companions reported evidence of a lower transition mass of ≤ 10 \, M Jup. When applied to the CLS sample, our model predicts the probability of a transition in the stellar metallicity distribution at or below 10 \, M Jup to be < 1 \%. We compare our results to estimates of γ gleaned from other observational metrics and discuss implications for planet formation theory.
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