Torques felt by solid accreting planets

TL;DR

This paper investigates how solid material accretion affects the torque and migration of low-mass planets in protoplanetary discs, revealing that accretion can significantly alter migration directions and magnitudes.

Contribution

It demonstrates through high-resolution simulations that solid accretion can enhance or reverse planetary migration torques, challenging traditional type-I migration predictions.

Findings

Solid accretion strengthens asymmetric solid patterns around planets.

Positive solid torque can overcome gas torque, causing outward migration.

Accretion effects vary with planet mass and solid size regime.

Abstract

The solid material of protoplanetary discs forms an asymmetric pattern around a low-mass planet (M_p<=10M_Earth) due to the combined effect of dust-gas interaction and the gravitational attraction of the planet. Recently, it has been shown that although the total solid mass is negligible compared to that of gas in protoplanetary discs, a positive torque can be emerged by a certain size solid species. The torque magnitude can overcome that of gas which may result in outward planetary migration. In this study, we show that the accretion of solid species by the planet strengthens the magnitude of solid torque being either positive or negative. We run two-dimensional, high-resolution (1.5Kx3K) global hydrodynamic simulations of an embedded low-mass planet in a protoplanetary disc. The solid material is handled as a pressureless fluid. Strong accretion of well-coupled solid species by a M_p<0.3M_Earth protoplanet results in the formation of such a strongly asymmetric solid pattern close to the planet that the positive solid torque can overcome that of gas by two times. However, the accretion of solids in the pebble regime results in increased magnitude negative torque felt by protoplanets and strengthened positive torque for Earth-mass planets. For M_p>=3M_Earth planets the magnitude of the solid torque is positive, however, independent of the accretion strength investigated. We conclude that the migration of solid accreting planets can be substantially departed from the canonical type-I prediction.