Solid accretion onto planetary cores in radiative disks
Abstract
The solid accretion rate, necessary to grow gas giant planetary cores within the disk lifetime, has been a major constraint for theories of planet formation. We tested the solid accretion rate efficiency on planetary cores of different masses embedded in their birth disk, by means of 3D radiation-hydrodynamics, where we followed the evolution of a swarm of embedded solids of different sizes. We found that using a realistic equation of state and radiative cooling, the disk at 5 au is able to cool efficiently and reduce its aspect ratio. As a result, the pebble isolation mass is reached before the core grows to 10 Earth masses, stopping efficiently the pebble flux and creating a transition disk. Moreover, the reduced isolation mass halts the solid accretion before the core reaches the critical mass, leading to a barrier to giant planet formation, and it explains the large abundance of super-Earth planets in the observed population.
Cite
@article{arxiv.2004.01745,
title = {Solid accretion onto planetary cores in radiative disks},
author = {Apostolos Zormpas and Giovanni Picogna and Barbara Ercolano and Wilhelm Kley},
journal= {arXiv preprint arXiv:2004.01745},
year = {2020}
}
Comments
Published in A&A, 8 pages, 9 figures