The ALMA survey to Resolve exoKuiper belt Substructures (ARKS) II. The radial structure of debris discs

TL;DR

This study uses high-resolution ALMA observations to analyze the radial structures of 24 debris discs, revealing diverse substructures, narrower rings than previously thought, and potential links to planetary influences and evolutionary processes.

Contribution

It provides detailed characterization of debris disc substructures using advanced modelling, highlighting differences from protoplanetary discs and suggesting mechanisms shaping debris disc architecture.

Findings

Many discs host multiple or single rings with halos or additional features.

Ring widths are narrower than previously measured and similar to protoplanetary discs.

Discs with steep inner edges are smaller and possibly shaped by planets.

Abstract

The ALMA survey to Resolve exoKuiper belt Substructures (ARKS) was recently completed to cover the lack of high-resolution observations of debris discs and to investigate the prevalence of substructures such as radial gaps and rings in a sample of 24 discs. This study characterises the radial structure of debris discs in the ARKS programme. To identify and quantify the disc substructures, we modelled all discs with a range of non-parametric and parametric approaches. We find that of the 24 discs in the sample, 5 host multiple rings, 7 are single rings that display halos or additional low-amplitude rings, and 12 are single rings with at most tentative evidence of additional substructures. The fractional ring widths that we measured are significantly narrower than previously derived values, and they follow a distribution similar to the fractional widths of individual rings resolved in protoplanetary discs. However, there exists a population of rings in debris discs that are significantly wider than those in protoplanetary discs. We also find that discs with steep inner edges consistent with planet sculpting tend to be found at smaller (<100 au) radii, while more radially extended discs tend to have shallower edges more consistent with collisional evolution. An overwhelming majority of discs have radial profiles well-described by either a double power law or double-Gaussian parametrisation. While our findings suggest that it may be possible for some debris discs to inherit their structures directly from protoplanetary discs, there exists a sizeable population of broad debris discs that cannot be explained in this way. Assuming that the distribution of millimetre dust reflects the distribution of planetesimals, mechanisms that cause rings in protoplanetary discs to migrate or debris discs to broaden soon after formation may be at play, possibly mediated by planetary migration or scattering.