Planetesimal Formation with Particle Feedback

TL;DR

This paper discusses how particle feedback in protoplanetary disks enhances particle clumping, facilitating gravitational collapse into planetesimals, and explores the role of turbulence and feedback mechanisms in this process.

Contribution

It demonstrates that particle feedback promotes clumping and gravitational collapse of solids into planetesimals, providing new insights into planetesimal formation mechanisms.

Findings

Particle feedback induces particle overdensities in turbulent flows.

Overdensities can trigger gravitational collapse into large planetesimals.

MHD turbulence can aid the collapse process.

Abstract

Proposed mechanisms for the formation of km-sized solid planetesimals face long-standing difficulties. Robust sticking mechanisms that would produce planetesimals by coagulation alone remain elusive. The gravitational collapse of smaller solids into planetesimals is opposed by stirring from turbulent gas. This proceeding describes recent works showing that "particle feedback," the back-reaction of drag forces on the gas in protoplanetary disks, promotes particle clumping as seeds for gravitational collapse. The idealized streaming instability demonstrates the basic ability of feedback to generate particle overdensities. More detailed numerical simulations show that the particle overdensities produced in turbulent flows trigger gravitational collapse to planetesimals. We discuss surprising aspects of this work, including the large (super-Ceres) mass of the collapsing bound cluster, and the finding that MHD turbulence aids gravitational collapse.