Gas Disk Sizes from CO Line Observations: A Test of Angular Momentum Evolution

TL;DR

This study combines SMA and ALMA data to analyze CO and continuum disk sizes in 44 protoplanetary disks, testing models of angular momentum evolution and disk dynamics.

Contribution

It provides the first comprehensive comparison of CO and continuum sizes across a large sample, testing viscous and wind-driven evolution models.

Findings

CO sizes range from 50 to 1000 au, consistent with viscous and wind models.

CO emission is on average 2.9 times more extended than continuum emission.

No observed CO size evolution with stellar age between 0.5 and 20 Myr.

Abstract

The size of a disk encodes important information about its evolution. Combining new Submillimeter Array (SMA) observations with archival Atacama Large Millimeter Array (ALMA) data, we analyze mm continuum and CO emission line sizes for a sample of 44 protoplanetary disks around stars with masses of 0.15--2\,$M_{\odot}$ in several nearby star-forming regions. Sizes measured from $^{12}$CO line emission span from 50 to 1000\,au. This range could be explained by viscous evolution models with different $\alpha$ values (mostly of $10^{-4}-10^{-3}$) and/or a spread of initial conditions. The CO sizes for most disks are also consistent with MHD wind models that directly remove disk angular momentum, but very large initial disk sizes would be required to account for the very extended CO disks in the sample. As no CO size evolution is observed across stellar ages of 0.5--20\,Myr in this sample, determining the dominant mechanism of disk evolution will require a more complete sample for both younger and more evolved systems. We find that the CO emission is universally more extended than the continuum emission by an average factor of $2.9\pm1.2$. The ratio of the CO to continuum sizes does not show any trend with stellar mass, mm continuum luminosity, or the properties of substructures. The GO Tau disk has the most extended CO emission in this sample, with an extreme CO to continuum size ratio of 7.6. Seven additional disks in the sample show high size ratios ($\gtrsim4$) that we interpret as clear signs of substantial radial drift.