The End of Runaway: How Gap Opening Limits the Final Masses of Gas Giants
arXiv:1905.03887 · doi:10.1093/mnras/stz1322
Abstract
Gas giants are thought to form by runaway accretion: an instability driven by the self-gravity of growing atmospheres that causes accretion rates to rise super-linearly with planet mass. Why runaway should stop at a Jupiter or any other mass is unknown. We consider the proposal that final masses are controlled by circumstellar disc gaps (cavities) opened by planetary gravitational torques. We develop a fully time-dependent theory of gap formation and couple it self-consistently to planetary growth rates. When gaps first open, planetary torques overwhelm viscous torques, and gas depletes as if it were inviscid. In low-viscosity discs, of the kind motivated by recent observations and theory, gaps stay predominantly in this inviscid phase and planet masses finalize at $M_{\rm final}/M_\star\sim(Ωt_{\rm disc})^{0.07}(H/a)^{2.73}(GÏ_0/Ω^2)^{1/3}$, with $M_\star$ the host stellar mass, $Ω$ the planet's orbital angular velocity, $t_{\rm disc}$ the gas disc's lifetime, $H/a$ its aspect ratio, and $Ï_0$ its unperturbed density. This final mass is independent of the dimensionless viscosity $α$ and applies to large orbital distances, typically beyond $\sim$10 AU, where disc scale heights exceed planet radii. It evaluates to a few Jupiter masses at 10-100 AU, increasing gradually with distance as gaps become harder to open.
Accepted to MNRAS