Abstract
Black holes are the simplest objects in the universe. They correspond to extreme deformations of spacetime geometry, and can exist even devoid of matter. In general relativity, (electro)vacuum black holes are uniquely determined by their mass, charge and angular momentum. This feature follows from a uniqueness theorem, which can be evaded if one considers higher dimensions or matter fields coupled to gravity. Here we find that Einsteinian cubic gravity, a well-motivated modification of Einstein gravity that includes third-order curvature corrections in accordance with low-energy effective theory expectations, admits black hole solutions with charge greater than mass, when minimally coupled to a Maxwell field. Moreover, we find that, in this regime, there can be two asymptotically flat black holes with the same charge and mass, posing the first example of vacuum black hole nonuniqueness in four dimensions that is free from pathologies. Examination of these black hole's thermodynamics reveals that when two branches coexist only the larger black hole is thermodynamically stable, while the smaller branch has negative specific heat. Einsteinian cubic gravity unveils two further surprising features. The charged black holes do not possess an inner horizon, in contrast with the usual Reissner-Nordstr\"om spacetime, thus avoiding the need to resort to strong cosmic censorship to uphold determinism. In addition to black holes, there exists a one-parameter family of naked singularity spacetimes sharing the same mass and charge as the former, but not continuously connected with them. These naked singularities exist in the under-extremal regime, being present even in pure (uncharged) Einsteinian cubic gravity.
Highlights
A hallmark of the Einstein-Maxwell theory that combines general relativity (GR) with electrodynamics is the validity of the celebrated black hole uniqueness theorem [1,2,3]
We find that Einsteinian cubic gravity, a well-motivated modification of Einstein gravity that includes third-order curvature corrections in accordance with low-energy effective theory expectations, admits black hole solutions with charge greater than mass, when minimally coupled to a Maxwell field
We have demonstrated that static charged black hole (BH) in 4D Einsteinian cubic gravity (ECG) differ notoriously from their counterparts in GR in several aspects: nonuniqueness of regular solutions, noncompliance with the extremality bound, and the absence of an inner horizon
Summary
A hallmark of the Einstein-Maxwell theory that combines general relativity (GR) with electrodynamics is the validity of the celebrated black hole uniqueness theorem [1,2,3]. In 4D, ECG is the most general diffeomorphism-invariant metric theory of gravity up to cubic order in curvature, whose linearized spectrum on maximally symmetric backgrounds coincides with that of GR, and for which static spherically symmetric vacuum solutions are governed by a single equation of motion. A second branch of BHs exists, in addition to the usual Schwarzschild solution, but they show unreasonable pathological behavior They are necessarily small in Planck units and feature large curvatures near the horizon (indicating even higher derivative corrections should be included). By studying horizonless (but singular) solutions, we find continuously nonunique families of positive-energy naked singularities sharing the same global conserved charges
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