All 2D generalised dilaton theories from d≥ 4 gravities

Abstract

We demonstrate that generic two-dimensional Horndeski theories can arise from the reduction of pure gravities in d ≥ 4 dimensions, and therefore generic onshell configurations for the two-dimensional metric and scalar field correspond to genuine d-dimensional gravitational vacuum solutions. We discuss separately the two-dimensional Horndeski theories which can arise from the reduction of d-dimensional generally covariant gravitational actions built only from curvature invariants without covariant derivatives and possessing second-order equations of motion on 2 + (d-2) warped-product backgrounds. The discussion is subsequently extended to generic d-dimensional gravitational actions with this latter property. We establish a Birkhoff theorem for all gravitational theories whose reduction yields an integrable two-dimensional Horndeski theory, in which case static spherically symmetric solutions satisfy gtt grr = -1 in Schwarzschild gauge whereby the metric function gtt = -f is determined by an algebraic equation. We therefore propose to refer to all such theories as quasi-topological gravities. These results can be used to show in reverse that any d-dimensional static spherically symmetric and asymptotically flat spacetime satisfying gtt grr = -1 in Schwarzschild gauge with an invertible dependence of f on the ADM mass can be reconstructed explicitly as a vacuum solution to a d-dimensional gravitational theory. We discuss examples of regular black holes such as the Bardeen spacetime, which could not be obtained from polynomial and non-polynomial quasi-topological gravities involving only curvature invariants without covariant derivatives.