Dust Drift Timescales in Protoplanetary Disks at the Cusp of Gravitational Instability

TL;DR

This paper investigates dust drift timescales in protoplanetary disks, revealing that disks near gravitational instability have drift timescales comparable to stellar lifetimes, impacting dust evolution and planet formation theories.

Contribution

It introduces a method to determine gas surface density and dust drift timescales from ALMA observations, linking disk mass, stability, and dust lifetime.

Findings

Disks near gravitational instability have drift timescales similar to stellar ages.

Disk mass scales with stellar mass as Mdisk ~ Mstar / 5Qmin.

Profiles matching dust mass imply very short drift timescales.

Abstract

Millimeter emitting dust grains have sizes that make them susceptible to drift in protoplanetary disks due to a difference between their orbital speed and that of the gas. The characteristic drift timescale depends on the surface density of the gas. By comparing disk radii measurements from ALMA CO and continuum observations at millimeter wavelengths, the gas surface density profile and dust drift time can be self-consistently determined. We find that profiles which match the measured dust mass have very short drift timescales, an order of magnitude or more shorter than the stellar age, whereas profiles for disks that are on the cusp of gravitational instability, defined via the minimum value of the Toomre parameter, Qmin ~ 1-2, have drift timescales comparable to the stellar lifetime. This holds for disks with masses of dust > 5 MEarth across a range of absolute ages from less than 1 Myr to over 10 Myr. The inferred disk masses scale with stellar mass as Mdisk ~ Mstar / 5Qmin. This interpretation of the gas and dust disk sizes simultaneously solves two long standing issues regarding the dust lifetime and exoplanet mass budget and suggests that we consider millimeter wavelength observations as a window into an underlying population of particles with a wide size distribution in secular evolution with a massive planetesimal disk.