Marginally stable Schwarzschild-black-hole-non-minimally-coupled-Proca-field bound-state configurations

Abstract

It has recently been revealed that, in curved black-hole spacetimes, non-minimally coupled massive Proca fields may be characterized by the existence of poles in their linearized perturbation equations and may therefore develop exponentially growing instabilities. Interestingly, recent numerical computations [H. W. Chiang, S. Garcia-Saenz, and A. Sang, arXiv:2504.04779] have provided compelling evidence that the onset of monopole instabilities in the composed black-hole-field system is controlled by the dimensionless physical parameter μ r-, where μ is the proper mass of the non-minimally coupled Proca field and r- (-2α)1/3rH is the radial location of the pole [here α is the non-minimal coupling parameter of the Einstein-Proca theory and rH is the radius of the black-hole horizon]. In the present paper we use analytical techniques in order to explore the physical properties of critical (marginally-stable) composed Schwarzschild-black-hole-nonminimally-coupled-monopole-Proca-field configurations. In particular, we derive a remarkably compact analytical formula for the discrete spectrum \μ(rH,r-;n) \n=∞n=1 of Proca field masses which characterize the critical black-hole-monopole-Proca-field configurations in the dimensionless regime r- -rHrH1 of near-horizon poles. The physical significance of the analytically derived resonance spectrum stems from the fact that the critical field mass μcμ(rH,r-;n=1) marks the onset of instabilities in the Schwarzschild-black-hole-nonminimally-coupled-monopole-Proca-field system. In particular, composed black-hole-linearized-Proca-field configurations in the small-mass regime μ≤μc of the Proca field are stable.