Dynamical and observational properties of weakly Proca-charged black holes

TL;DR

This paper investigates weakly Proca-charged black holes using perturbation theory, analyzing their observational signatures such as gravitational bending, black hole shadow, and stellar orbit fits, with implications for photon mass constraints.

Contribution

It provides an analytical perturbative solution to Einstein-Proca equations for small charge and mass, and explores observational effects and constraints on photon mass near black holes.

Findings

Proca mass significantly affects dynamical equations despite being below experimental limits.

Black hole shadow only reveals photon mass effects for extremely cold photons.

Constraints on Proca parameter from Galactic center flare data suggest potential for future tests.

Abstract

The simplest approach to include a mass into the electromagnetic vector potential is to modify the Einstein-Maxwell action to the Einstein-Proca form. There are currently no exact analytical solutions for this scenario. However, by using perturbation theory, where both the Proca mass and the black hole charge are small parameters, it is possible to find an exact analytical solution. In this solution, the metric tensor remains unchanged, but the vector potential deviates from the Coulomb potential. In particular, even if the Proca mass is limited by the value $m_{\gamma}<10^{-48}\text{g}$, which is the current experimental upper limit for photon mass, it makes a significant contribution to the dynamical equations. In this paper, we study the motion of neutral and charged particles in the vicinity of a weakly Proca-charged black hole, and test the observational implications of the solution of the Einstein-Proca equations for gravitational bending, the black hole shadow, and the fit to the orbits of the Galactic center flares observed by the near-infrared GRAVITY instrument. We find that only extremely cold photons, which are likely scattered before reaching a distant observer, could reveal the non-zero photon mass effect through the black hole shadow. For the Galactic center flare analysis we obtained constraints on the dimensionless Proca parameter to $\mu \leq 0.125$ for the electric interaction parameter in the range $-1.1 < \mathrm{Q} < 0.5$, which can be potentially tested by future GRAVITY flare astrometry. Since the Proca parameter is coupled to the black hole mass, the effect of the Proca charge becomes more pronounced for supermassive black holes compared to stellar-mass objects. Our perturbative treatment remains valid essentially up to the horizon, with divergences appearing only in the immediate near-horizon region, where a fully non-perturbative analysis would be required.