Surface accretion as a dust retention mechanism in protoplanetary disks. I. Formulation and proof-of-concept simulations

TL;DR

This paper introduces a new dust retention mechanism in protoplanetary disks driven by MHD winds, which enhances dust concentration and could facilitate planetesimal formation despite smaller observed grain sizes.

Contribution

It proposes and models a surface accretion flow mechanism that retains dust in disks with slowly drifting grains, a novel approach to dust retention in planet formation.

Findings

Significant increase in midplane dust-to-gas ratio under certain conditions.

Surface accretion flows can prevent dust loss despite slow grain drift.

Potential pathway for planetesimal formation from less sticky grains.

Abstract

Planetesimal formation via the streaming and gravitational instabilities of dust in protoplanetary disks requires a local enhancement of the dust-to-gas mass ratio. Radial drift of large grains toward pressure bumps in gas disks is a plausible mechanism for achieving the required dust concentration. However, recent millimeter disk observations suggest that the maximum sizes of dust grains in these disks are considerably smaller than predicted by dust evolution models that assume sticky grains. This indicates that the grains may be more strongly coupled to the gas and hence drift more slowly than previously anticipated. In this study, we propose a new dust retention mechanism that enables an enhancement of the dust-to-gas mass ratio in disks with slowly drifting grains. This mechanism assumes that a surface accretion flow driven by magnetohydrodynamical (MHD) winds removes disk gas while retaining the slowly drifting grains below the flow. This process is expected to occur when the timescale of gas removal is shorter than the timescale of dust radial advection. To test this, we develop a radially one-dimensional framework for the transport of gas and dust in a disk with a vertically nonuniform accretion structure. Using this framework, we simulate the growth, fragmentation, and radial transport of dust grains in surface-accreting disks. Our simulations confirm a significant enhancement of the midplane dust-to-gas mass ratio when the predicted conditions for dust retention are met. Dust retention by MHD-driven surface accretion flows may thus pave the way for planetesimal formation from poorly sticky grains.