Extended thermodynamics of the bumblebee black holes

Abstract

As a vector-tensor theory including nonminimal coupling between the Ricci tensor and a vector field, the bumblebee gravity is a potential theory to test Lorentz symmetry violation. Recently, a new class of numerical spherical black holes in the bumblebee theory was constructed. In this paper, we investigate the associated local thermodynamic properties. By introducing a pair of conjugated thermodynamic quantities X and Y, which can be interpreted as an extension of electric potential and charge of the Reissner Nordstr\"om black holes, we numerically construct a new first law of thermodynamics for bumblebee black holes. We then study the constant-Y processes in the entropy-charge parameter space. For the constant-Y processes, we also calculate the heat capacity to study the local thermodynamic stability of the bumblebee black holes. For a negative nonminimal coupling coefficient , we find both divergent and smooth phase transitions. For a positive but small , only a divergent phase transition is found. It turns out that there is a critical value 0.4 <c < 0.5 such that when c < <2, even the divergent phase transition disappears and the bumblebee black holes thus become locally thermodynamically unstable regardless of the bumblebee charge. As for >2, the smooth phase transition arises again but there no longer exists any discontinuous phase transition for the bumblebee black holes.