Unlocking the secrets of the midplane gas and dust distribution in the young hybrid disc HD 141569

TL;DR

This study provides the first detection of optically thin gas emission from the midplane of the hybrid disc HD 141569, revealing detailed gas and dust distribution and mass estimates that clarify previous underestimations.

Contribution

First imaging of optically thin gas emission from HD 141569's midplane, offering new insights into its structure and mass in the context of disc evolution.

Findings

Detected asymmetrical $^{13}$CO distribution around the star.

Measured disc gas mass as (6.0±0.9)×10^{-4} M_sun.

Revealed $^{12}$CO optical thickness causes underestimation of gas mass.

Abstract

HD141569 is a pre-main sequence star with a disc uniquely placed between protoplanetary and debris discs, similar to the older `hybrid' type discs. This work aims to place the mass and spatial structure of the disc midplane in the context of the debris, hybrid and protoplanetary discs. We observed HD~141569 with ALMA in 1.3~mm continuum and $^{13}$CO (2-1). This is the first detection and image of the optically thin gas emission from the midplane of this disc. In continuum emission, we detect a combination of an unresolved central peak and a ring of millimetre emission at 220$\pm$10~au, slightly interior to one of the rings discovered in scattered light. The minimum dust mass of the ring is 0.13$\pm$0.02~M$_{\oplus}$ while the unresolved millimetre peak at the stellar location is predominantly thermal emission due to a minimum of 1.2$\pm$0.2~M$_{\oplus}$ of dust. $^{13}$CO is distributed asymmetrically around the stellar position with a peak at 1.1" distance and a P.A. of -33$^\circ$. The gas is detected as far as 220$\pm$10~au, a radial separation the same as that of the mm ring. Assuming optically thin emission and standard ISM abundances, we use our $^{13}$CO data to derive the gas mass in the disc of (6.0$\pm$0.9) $\times 10^{-4}~$M$_\odot$. Comparison to published $^{12}$CO data shows that $^{12}$CO is optically thick, explaining why estimates based on $^{12}$CO underestimated the gas mass.