Accretion in a dynamical spacetime and spinning up of the black hole in the gamma ray burst central engine

TL;DR

This paper models the evolution of a slowly rotating accretion flow around a black hole during a gamma-ray burst, highlighting how mass and spin change dynamically and impact black hole properties and observational constraints.

Contribution

It introduces a model for accretion in a dynamical spacetime during GRBs, accounting for evolving black hole mass and spin in a transient event.

Findings

Black hole mass and spin increase during accretion in GRBs.

Shocks may form and influence accretion temporarily.

Constraints on black hole final parameters based on progenitor rotation.

Abstract

We compute the evolution of a quasi-spherical, slowly rotating accretion flow around a black hole, whose mass and spin evolve adequately to the mass-energy transfer through the horizon. Our model is relevant for the central engine driving a long gamma ray burst, that originates from the collapse of a massive star. The computations of a GRB engine in a dynamically evolving spacetime metric are important specifically due to the transient nature of the event, in which a huge amount of mass is accreted and changes the fundamental black hole parameters, its mass and spin, during the process. We discuss the results in the context of angular momentum magnitude of the collapsing star. We also study the possible formation and evolution of shocks in the envelope, which may temporarily affect accretion. Our results are important for the limitations on the mass and spin range of black holes detected independently by electromagnetic observations of GRBs and gravitational waves. We speculate on the possible constraints for the final masses and spins of these astrophysical black holes. It is shown that the most massive BHs were rahter not formed in a powerful GRB explosion, if the cores of their progenitors were only weakly rotating.