The observed exoplanet population features a gap in the radius distribution that separates the smaller super-Earths (≲1.7 Earth radii) from the larger sub-Neptunes (∼1.7–4 Earth radii). While mass-loss theories can explain many of the observed features of this radius valley, it is difficult to reconcile them with the potentially rising population of terrestrials beyond orbital periods of ∼30 days. We investigate the ability of gas accretion during the gas-poor phase of disk evolution to reproduce both the location of the observed radius gap and the existence of long-period terrestrial planets. Updating the analytic scaling relations of gas accretion rate accounting for the shrinking of the bound radius by hydrodynamic effects and deriving a more realistic disk temperature profile, we find that the late-stage gas accretion alone is able to carve out the observed radius gap, with slopes R gap ∝ P −0.096 and R gap ∝ M ⋆ 0.15 for top-heavy; and R gap ∝ P −0.089 and R gap ∝ M ⋆ 0.22 for bottom-heavy core mass distributions, in good agreement with observations. The general morphology of the primordial radius gap is stable against a range of disk gas density and disk accretion rate with the latter affecting mostly the population of large planets (≳3–4 R ⊕). The peaks and valleys in the radius distribution were likely set in place primordially while post-formation mass loss further tunes the exoplanetary population. We provide potential observational tests that may be possible with TESS, PLATO, and Roman Space Telescope.
The observed exoplanet population features a gap in the radius distribution that separates the smaller super-Earths ( 1.7𝑅 ⊕ ) from the larger sub-Neptunes (∼1.7-4𝑅 ⊕ ). While mass loss theories can explain many of the observed features of this radius valley, it is difficult to reconcile them with a potentially rising population of terrestrials beyond orbital periods of 30 days. We investigate the ability of initial gas accretion to reproduce both the location of the observed radius gap and the existence of long-period terrestrials. We first update the analytic scalings of gas accretion rate accounting for the shrinking of the bound radius by hydrodynamic effects. From the cooling evolution of planetary envelope with realistic opacity and equation of state, we find that the envelope mass fraction depends only weakly with the radius shrinking factor (𝑀 gas /𝑀 core ∝ 𝑓 0.31 𝑅 ). Co-evolving planetary masses and disk structures, focussing on dust-free opacity, we find that gas accretion alone is able to carve out the observed radius gap, with slopes 𝑅 gap ∝ 𝑃 −0.11 and 𝑅 gap ∝ 𝑀 0.24 ★ for top-heavy; and 𝑅 gap ∝ 𝑃 −0.10 and 𝑅 gap ∝ 𝑀 0.21 ★ for bottom-heavy core mass distributions, in good agreement with observations. Our model reconciles the location of the radius gap with the existence of long period terrestrials. The peaks and valleys in the radius distribution were likely set in place primordially while post-formation processes further tune the exoplanetary population. We provide potential observational tests that may be possible with PLATO and Roman Space Telescope.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
