📝 SummarXiv

Abstract

Post-Asymptotic Giant Branch (post-AGB) binary stars are evolved systems that host circumbinary discs formed through mass loss during late-stage binary interaction. Their structural, kinematic, and chemical similarities to planet-forming discs have motivated the idea that these systems may act as sites of "second-generation" planet formation. In this study, we assess whether the gravitational instability mechanism - a proposed pathway for giant planet formation in some protoplanetary discs-can operate in post-AGB discs. Using the Toomre criterion under well-motivated assumptions for disc structure and size, mass, and thermal properties, we assess the conditions for gravitational instability. We first benchmark our analytical framework using several well-studied protoplanetary disc systems before applying the same analysis to observed post-AGB discs. We find that post-AGB discs are generally gravitationally stable at present, due primarily to their low masses. The disks were stable against collapse, even when accounting for potentially higher disk mass in the past. In contrast, several protoplanetary discs analysed in the same way show that they likely experienced gravitationally unstable phases early on. Finally, we revisit the planet formation scenario proposed for the post-common envelope system NN Serpentis first carried out by Schleicher and Dreizler and we show that gravitational instability could be feasible under specific, high disc mass assumptions, however we note that their proposed disc mass is unlikely. Overall, our results provide the first systematic theoretical assessment of gravitational instability in post-AGB discs, demonstrating that this mechanism is unlikely to dominate second-generation planet formation in these systems, and underscoring the need to explore alternative pathways-such as core accretion-in future studies