The origin and evolution of transition discs: successes, problems and open questions

TL;DR

This review explores the origins and evolution of transition discs, highlighting two distinct populations, evaluating proposed formation mechanisms, and identifying key gaps in current theoretical understanding to better inform planet formation models.

Contribution

It provides a comprehensive comparison of observed transition disc populations with theoretical models, emphasizing the need for further research on their formation mechanisms.

Findings

Identification of two distinct transition disc populations: mm-faint and mm-bright.

Evidence that mm-bright discs are rare, long-lived, and not explained by simple dispersal models.

Highlighting the need for more theoretical work on non-accreting transition discs.

Abstract

Transition discs are protoplanetary discs that show evidence for large holes or wide gaps (with widths comparable to their radii) in their dust component. These discs could be giving us clues about the disc destruction mechanism or hints about the location and time-scales for the formation of planets. However, at the moment there remain key gaps in our theoretical understanding. The vast majority of transition discs are accreting onto their central stars, indicating that - at least close to the star - dust has been depleted from the gas by a very large amount. In this review, we discuss evidence for two distinct populations of transition discs: mm-faint - those with low mm-fluxes, small holes ($\lesssim$10AU) and low accretion rates (~1e-10-1e-9 Msun/yr) and mm-bright - discs with large mm-fluxes, large holes ($\gtrsim$20 AU) and high accretion rates ~1e-8 Msun/yr. MM-faint transition discs are consistent with what would naively be expected from a disc undergoing dispersal; however, mm-bright discs are not, and are likely to be rare and long-lived objects. We discuss the two commonly proposed mechanisms for creating transition discs: photoevaporation and planet-disc interactions, with a particular emphasis on how they would evolve in these models, comparing these predictions to the observed population. More theoretical work on explaining the lack of optically thick, non-accreting transition discs is required in both the photoevaporation and planetary hypothesis, before we can start to use transition discs to constrain models of planet formation. Finally, we suggest that the few discs with primordial looking SEDs, but serendipitously imaged, showing large cavities in the mm (e.g. MWC758 & WSB 60) may represent a hidden population of associated objects. Characterising and understanding how these objects fit into the overall paradigm may allow us to unravel the mystery of transition discs.