To Cool is to Accrete: Analytic Scalings for Nebular Accretion of Planetary Atmospheres

Abstract

Planets acquire atmospheres from their parent circumstellar disks. We derive a general analytic expression for how the atmospheric mass grows with time t, as a function of the underlying core mass M core and nebular conditions, including the gas metallicity Z. Planets accrete as much gas as can cool: an atmosphere's doubling time is given by its Kelvin-Helmholtz time. Dusty atmospheres behave differently from atmospheres made dust-free by grain growth and sedimentation. The gas-to-core mass ratio (GCR) of a dusty atmosphere scales as GCR t0.4 M core1.7 Z-0.4 μ rcb3.4, where μ rcb 1/(1-Z) (for Z not too close to 1) is the mean molecular weight at the innermost radiative-convective boundary. This scaling applies across all orbital distances and nebular conditions for dusty atmospheres; their radiative-convective boundaries, which regulate cooling, are not set by the external environment, but rather by the internal microphysics of dust sublimation, H2 dissociation, and the formation of H-. By contrast, dust-free atmospheres have their radiative boundaries at temperatures T rcb close to nebular temperatures T out, and grow faster at larger orbital distances where cooler temperatures, and by extension lower opacities, prevail. At 0.1 AU in a gas-poor nebula, GCR t0.4 T rcb-1.9 M core1.6 Z-0.4 μ rcb3.3, while beyond 1 AU in a gas-rich nebula, GCR t0.4 T rcb-1.5 M core1 Z-0.4μ rcb2.2. We confirm our analytic scalings against detailed numerical models for objects ranging in mass from Mars (0.1 M) to the most extreme super-Earths (10-20 M), and explain why heating from planetesimal accretion cannot prevent the latter from undergoing runaway gas accretion.