The Anatomy of an Unusual Edge-on Protoplanetary Disk I. Dust Settling in a Cold Disk

TL;DR

This study uses multi-wavelength high-resolution imaging to analyze the structure and dust settling in a rare, flat edge-on protoplanetary disk, revealing insights into early planet formation processes.

Contribution

It provides a detailed multi-epoch observational analysis and modeling of a unique flat edge-on disk, highlighting dust settling and complex radial structure.

Findings

Evidence of dust settling in the disk

The disk is well modeled as a flared structure with an exponential outer edge

Residual radial substructures suggest more complex density profiles

Abstract

As the earliest stage of planet formation, massive, optically thick, and gas rich protoplanetary disks provide key insights into the physics of star and planet formation. When viewed edge-on, high resolution images offer a unique opportunity to study both the radial and vertical structures of these disks and relate this to vertical settling, radial drift, grain growth, and changes in the midplane temperatures. In this work, we present multi-epoch HST and Keck scattered light images, and an ALMA 1.3 mm continuum map for the remarkably flat edge-on protoplanetary disk SSTC2DJ163131.2-242627, a young solar-type star in $\rho$ Ophiuchus. We model the 0.8 $\mu$m and 1.3 mm images in separate MCMC runs to investigate the geometry and dust properties of the disk using the MCFOST radiative transfer code. In scattered light, we are sensitive to the smaller dust grains in the surface layers of the disk, while the sub-millimeter dust continuum observations probe larger grains closer to the disk midplane. An MCMC run combining both datasets using a covariance-based log-likelihood estimation was marginally successful, implying insufficient complexity in our disk model. The disk is well characterized by a flared disk model with an exponentially tapered outer edge viewed nearly edge-on, though some degree of dust settling is required to reproduce the vertically thin profile and lack of apparent flaring. A colder than expected disk midplane, evidence for dust settling, and residual radial substructures all point to a more complex radial density profile to be probed with future, higher resolution observations.