Investigating the Relative Gas and Small Dust Grain Surface Heights in Protoplanetary Disks

TL;DR

This study compares the vertical distribution of small dust grains and gas in three protoplanetary disks, revealing differences at larger radii and suggesting high gas-to-dust ratios influence dust settling.

Contribution

It provides the first direct observational comparison of gas and small dust grain height distributions in protoplanetary disks, combining observations and modeling.

Findings

At radii >100 au, dust grains are lower than gas in two disks.

Gas-to-dust ratios >100 can explain observed height differences.

Radiative transfer modeling shows no difference between scattering and CO emission surfaces.

Abstract

Dust evolution in protoplanetary disks from small dust grains to pebbles is key to the planet formation process. The gas in protoplanetary disks should influence the vertical distribution of small dust grains ($\sim$1 $\mu m$) in the disk.Utilizing archival near-infrared polarized light and millimeter observations, we can measure the scale height and the flare parameter $\beta$ of the small dust grain scattering surface and $^{12}$CO gas emission surface for three protoplanetary disks IM Lup, HD 163296, and HD 97048 (CU Cha). For two systems, IM Lup and HD 163296, the $^{12}$CO gas and small dust grains at small radii from the star have similar heights but at larger radii ($>$100 au) the dust grain scattering surface height is lower than the $^{12}$CO gas emission surface height. In the case of HD 97048, the small dust grain scattering surface has similar heights to the $^{12}$CO gas emission surface at all radii. We ran a protoplanetary disk radiative transfer model of a generic protoplanetary disk with TORUS and showed that there is no difference between the observed scattering surface and $^{12}$CO emission surface. We also performed analytical modeling of the system and found that gas-to-dust ratios larger than 100 could explain the observed difference in IM Lup and HD 163296. This is the first direct comparison of observations of gas and small dust grain heights distribution in protoplanetary disks. Future observations of gas emission and near-infrared scattered light instruments are needed to look for similar trends in other protoplanetary disks.