The Arduous Journey to Black-Hole Formation in Potential Gamma-Ray Burst Progenitors

TL;DR

This study investigates the conditions under which massive, fast-rotating, low-metallicity stars can form black holes or proto-magnetars, highlighting the complexity of LGRB progenitor models and the importance of multiple stellar properties.

Contribution

It provides a detailed analysis of stellar-collapse simulations showing that black-hole formation requires specific conditions, and challenges the simplified criteria used in the community for LGRB progenitor assessment.

Findings

Only the fastest rotating progenitors form black holes.

Most models retain enough angular momentum for magneto-rotational explosions.

Proto-magnetars are more easily produced than collapsars in current models.

Abstract

We present a quantitative study on the properties at death of fast-rotating massive stars evolved at low-metallicity, objects that are proposed as likely progenitors of long-duration gamma-ray bursts (LGRBs). We perform 1D+rotation stellar-collapse simulations on the progenitor models of Woosley & Heger (2006) and critically assess their potential for the formation of a black hole and a Keplerian disk (namely a collapsar) or a proto-magnetar. We note that theoretical uncertainties in the treatment of magnetic fields and the approximate handling of rotation compromises the accuracy of stellar-evolution models. We find that only the fastest rotating progenitors achieve sufficient compactness for black-hole formation while the bulk of models possess a core density structure typical of garden-variety core-collapse supernova (SN) progenitors evolved without rotation and at solar metallicity. Of the models that do have sufficient compactness for black-hole formation, most of them also retain a large amount of angular momentum in the core, making them prone to a magneto-rotational explosion, therefore preferentially leaving behind a proto-magnetar. A large progenitor angular-momentum budget is often the sole criterion invoked in the community today to assess the suitability for producing a collapsar. This simplification ignores equally important considerations such as the core compactness, which conditions black-hole formation, the core angular momentum, which may foster a magneto-rotational explosion preventing black-hole formation, or the metallicity and the residual envelope mass which must be compatible with inferences from observed LGRB/SNe. Our study suggests that black-hole formation is non trivial, that there is room for accommodating both collapsars and proto-magnetars as LGRB progenitors, although proto-magnetars seem much more easily produced by current stellar-evolutionary models.