Rotating black holes in valid vector-tensor theories after GW170817

TL;DR

This paper constructs and analyzes rotating black hole solutions in vector-tensor theories consistent with GW170817 constraints, revealing preserved horizon structures but altered separability and orbital properties, with implications for astrophysical observations.

Contribution

It introduces a new class of rotating black hole solutions in vector-tensor theories valid after GW170817, extending beyond generalized Proca theories and analyzing their properties.

Findings

Preserve horizon, singularity, and ergoregion structure from Kerr-Newman.

Hamilton-Jacobi equation is not separable; Carter-like constant absent.

Bounds on deviations from Kerr-Newman from Sgr A* precession measurements.

Abstract

Vector-tensor theories beyond General Relativity have widely been studied in the context of ultraviolet completion of gravity, endowing a mass to the graviton and explaining dark energy phenomena. We here construct rotating black hole solutions in vector-tensor theories valid after the binary neutron star merger event GW170817 that placed very stringent bound on the propagation speed of gravitational waves away from the speed of light. Such valid vector-tensor theories are constructed by performing a generic conformal transformation to Einstein-Maxwell theory, and the new rotating black hole solutions are constructed by applying the same conformal transformation to the Kerr-Newman solution. These theories fall outside of beyond generalized Proca theories but are within an extended class of vector-tensor theories that satisfy a degenerate condition to eliminate instability modes and are thus healthy. We find that such conformal Kerr-Newman solutions preserve the location of the singularities, event horizons and ergoregion boundary from Kerr-Newman, as well as the multipole moments and the Petrov type. On the other hand, the Hamilton-Jacobi equation is no longer separable, suggesting that the Carter-like constant does not exist in this solution. The standard Newman-Janis algorithm also does not work to construct the new solutions. We also compute the epicyclic frequencies, the location of the innermost stable circular orbits, and the Schwarzschild precession and apply the latter to the recent GRAVITY measurement to place bounds on the deviations away from Kerr-Newman for Sgr A$^*$.