Structure and Composition of Two Transitional Circumstellar Disks in Corona Australis

TL;DR

This study investigates the structure and composition of two ~10 million-year-old circumstellar disks in Corona Australis, revealing inner cavities and signs of ongoing gas clearing, which are important for understanding planet formation.

Contribution

The paper presents new high-resolution observations and detailed modeling of two transitional disks, providing insights into their structure and gas dissipation processes.

Findings

Inner cavities of 16 AU and 5 AU identified in the disks.

Evidence of gas clearing underway in both disks.

Lower than expected CO content indicating gas dispersal.

Abstract

The late stages of evolution of the primordial circumstellar disks surrounding young stars are poorly understood, yet vital to constrain theories of planet formation. We consider basic structural models for the disks around two ~10 Myr-old members of the nearby RCrA association, RX J1842.9-3532 and RX J1852.3-3700. We present new arcsecond-resolution maps of their 230 GHz continuum emission from the Submillimeter Array and unresolved CO(3-2) spectra from the Atacama Submillimeter Telescope Experiment. By combining these data with broadband fluxes from the literature and infrared fluxes and spectra from the catalog of the Formation and Evolution of Planetary Systems (FEPS) Legacy program on the Spitzer Space Telescope, we assemble a multiwavelength data set probing the gas and dust disks. Using the Monte Carlo radiative transfer code RADMC to model simultaneously the SED and millimeter continuum visibilities, we derive basic dust disk properties and identify an inner cavity of radius 16 AU in the disk around RX J1852.3-3700. We also identify an optically thin 5 AU cavity in the disk around RX J1842.9-3532, with a small amount of optically thick material close to the star. The molecular line observations suggest an intermediate disk inclination in RX J1842.9-3532, consistent with the continuum emission. In combination with the dust models, the molecular data allow us to derive a lower CO content than expected, suggesting that the process of gas clearing is likely underway in both systems, perhaps simultaneously with planet formation.