Litcius/Paper detail

Three-dimensional Transport of Solids in a Protoplanetary Disk Containing a Growing Giant Planet

Eric Van Clepper, Ellen M. Price, F. J. Ciesla

2025The Astrophysical Journal13 citationsDOIOpen Access PDF

Abstract

Abstract We present the results of combined hydrodynamic and particle tracking post-processing modeling to study the transport of small dust in a protoplanetary disk containing an embedded embryo in three dimensions. We use a suite of FARGO3D hydrodynamic simulations of disks containing a planetary embryo varying in mass up to 300 M ⊕ on a fixed orbit in both high- and low-viscosity disks. We then simulate solid particles through the disk as a post-processing step using a Monte Carlo integration, allowing us to track the trajectories of individual particles as they travel throughout the disk. We find that gas advection onto the planet can carry small, well-coupled solids across the gap opened in the disk by the embedded planet for planetary masses above the pebble isolation mass. This mixing between the inner and outer disk can occur in both directions, with solids in the inner disk mixing to the outer disk as well. Additionally, in low-viscosity disks, multiple dust pile-ups in the outer disk may preserve isotopic heterogeneities, possibly providing an outermost tertiary isotopic reservoir. Throughout Jupiter's growth, the extent of mixing between isotopic reservoirs varied depending on dust size, gas turbulence, and the Jovian embryo mass.

Topics & Concepts

PhysicsPlanetProtoplanetary diskAstrobiologyAstronomyAstrophysicsProtoplanetPlanetesimalGiant planetPlanetary systemAccretion (finance)Astro and Planetary ScienceAstrophysics and Star Formation StudiesStellar, planetary, and galactic studies