Fuzzy-novae

Abstract

We propose a novel phenomenological model of quantum gravitational collapse inspired by loop quantum gravity that ensures a completely regular spacetime evolution. By incorporating quantum gravitational modifications based on local rather than average energy density, our model simultaneously resolves both the central singularity and the shell-crossing singularities. Numerical simulations reveal that the interplay between local quantum repulsion and gravitational attraction leads to the formation of a stable, outgoing solitary matter wave, supported by a dynamical local anti-trapped region. This mechanism allows for a time-like ejection of the entire stellar mass -- a fuzzy-nova -- which signals the end of macroscopic black holes. By providing a concrete dynamical mechanism for matter to escape the trapped region, our work sets a new stage for resolving the information paradox and opens a realistic observational window into quantum gravity.