Gravitational analog of the canonical acoustic black hole in Einstein-scalar-Gauss-Bonnet theory

Abstract

In this work, in the context of modified gravity, a curved spacetime analogous to the "canonical acoustic black hole" is constructed. The source is a self-interacting scalar field which is non-minimally coupled to gravity through the Gauss-Bonnet invariant. The scalar-Gauss-Bonnet coupling function is characterized by three positive parameters: σ with units of (length), μ with units of (length)4, and a dimensionless parameter s, thus defining a three-parameter model for which the line element of canonical acoustic black hole is a solution. The spacetime is equipped with spherical and static symmetry and has a single horizon determined in Schwarzschild coordinates by the region r=μ1/4. The solution admits a photon sphere at r=(3μ)1/4, and it is shown that in the region (3μ)1/4≤ r<∞ the scalar field satisfies the null, weak, and strong energy conditions. Nonetheless, the model with s=1 has major physical relevance since for this case the scalar field is well defined in the entire region r≥μ1/4, while for s≠1 the scalar field blows up on the horizon.