Pebble dynamics and accretion onto rocky planets. I. Adiabatic and convective models

Abstract

We present nested-grid, high-resolution hydrodynamic simulations of gas and particle dynamics in the vicinity of Mars- to Earth-mass planetary embryos. The simulations extend from the surface of the embryos to a few vertical disk scale heights, with a spatial dynamic range of \! 1.4× 105. Our results confirm that "pebble"-sized particles are readily accreted, with accretion rates continuing to increase up to metre-size "boulders" for a 10\% MMSN surface density model. The gas mass flux in and out of the Hill sphere is consistent with the Hill rate, RH2 = 4\, 10-3 M yr-1. While smaller size particles mainly track the gas, a net accretion rate of ≈ 2\,10-5 M yr-1 is reached for 0.3--1 cm particles, even though a significant fraction leaves the Hill sphere again. Effectively all pebble-sized particles that cross the Bondi sphere are accreted. The resolution of these simulations is sufficient to resolve accretion-driven convection. Convection driven by a nominal accretion rate of 10-6 M yr-1 does not significantly alter the pebble accretion rate. We find that, due to cancellation effects, accretion rates of pebble-sized particles are nearly independent of disk surface density. As a result, we can estimate accurate growth times for specified particle sizes. For 0.3--1 cm size particles, the growth time from a small seed is 0.15 million years for an Earth mass planet at 1 AU and 0.1 million years for a Mars mass planet at 1.5 AU.