Listening to black mirrors with gravitational radiation

TL;DR

This paper proposes that gravitational wave observations can distinguish black mirrors, a CPT-symmetric alternative to classical black holes, from traditional black holes by analyzing their unique quasi-normal mode spectra and reflectivity properties.

Contribution

It introduces a testable signature of black mirrors via gravitational waves, highlighting their universal reflectivity and impact on inspiral dynamics, differing from classical black holes.

Findings

Black mirrors have a distinct quasi-normal mode spectrum.

The reflectivity of black mirrors is given by a generalized Boltzmann factor.

Black mirrors alter inspiral dynamics, especially at high spins.

Abstract

The existence of curvature singularities and the information and firewall paradoxes are significant problems for the conventional black hole model. The black mirror provides a CPT-symmetric alternative to the classical description. We show that classical black holes can be distinguished from black mirrors by using gravitational waves. The principal challenge is to identify a unique, testable signature of the black mirror's reflective horizon that can be detected. The horizon singularity of the black mirror model necessitates that no energy flux is propagated beyond the horizon, which can be described effectively by imposing specific boundary conditions at the event horizon. We demonstrate that the quasi-normal mode spectrum of the black mirror is fundamentally different from that of classical black holes. We derive the reflectivity of the black mirror and find it is given precisely by the generalized Boltzmann factor. Moreover, we show that this is a universal behaviour: regardless of the specific details of the unknown quantum gravity interactions, the macroscopic reflectivity is dictated solely by the Hawking temperature $T_H$. This drastically alters the orbital dynamics of extreme-mass ratio inspirals. For low spins, the inspiral decelerates due to reduced absorption. For high spins and prograde orbits, the black mirror suppresses the superradiant amplification of classical black holes, acting instead as an absorber. This leads to an inspiral that proceeds faster than the classical prediction. Finally, we show that this model allows for the cosmic growth of supermassive black holes to high spins via accretion. A definitive detection of these signatures would provide compelling evidence distinguishing the reflective boundary of a black mirror from the perfectly absorbing horizon of a classical black hole.