Resolved millimeter-dust continuum cavity around the very low mass young star CIDA 1

TL;DR

This paper reports the discovery of a large dust cavity in the disk around the very low mass star CIDA 1 using ALMA observations, providing insights into disk evolution and planet formation around such stars.

Contribution

First detection of a millimeter dust cavity in a very low mass star's disk, highlighting potential planet formation mechanisms in low-mass stellar environments.

Findings

Cavity radius of about 20 au detected in CIDA 1's disk.

CIDA 1 has a relatively massive disk for its stellar mass.

High accretion rate despite the large dust cavity.

Abstract

Context. Transition disks (TDs) are circumstellar disks with inner regions highly depleted in dust. TDs are observed in a small fraction of disk-bearing objects at ages of 1-10 Myr. They are important laboratories to study evolutionary effects in disks, from photoevaporation to planet-disk interactions. Aims. We report the discovery of a large inner dust-empty region in the disk around the very low mass star CIDA 1 (M$_{\star} \sim 0.1-0.2$ M$_{\odot}$). Methods. We used ALMA continuum observations at 887$\mu$m, which provide a spatial resolution of $0."21\times0."12$ ($\sim$15$\times$8 au in radius at 140 pc). Results. The data show a dusty ring with a clear cavity of radius $\sim$20 au, the typical characteristic of a TD. The emission in the ring is well described by a narrow Gaussian profile. The dust mass in the disk is $\sim$17 M$_{\oplus}$. CIDA 1 is one of the lowest mass stars with a clearly detected millimeter cavity. When compared to objects of similar stellar mass, it has a relatively massive dusty disk (less than $\sim5$% of Taurus Class II disks in Taurus have a ratio of $M_{\rm{disk}}/M_{\star}$ larger than CIDA 1) and a very high mass accretion rate (CIDA 1 is a disk with one of the lowest values of $M_{\rm{disk}}/\dot M$ ever observed). In light of these unusual parameters, we discuss a number of possible mechanisms that can be responsible for the formation of the dust cavity (e.g., photoevaporation, dead zones, embedded planets, close binary). We find that an embedded planet of a Saturn mass or a close binary are the most likely possibilities.