Off-shell Hessian thermodynamic stability of higher-curvature black holes

Abstract

We develop a branch-sensitive thermodynamic framework for higher-curvature black holes using the off-shell Gibbs free energy G off and the Wald entropySW as the basic data. On fixed-parameter slices, equilibrium black holes are stationary points of G off, and their local stability is governed by the Hessian H=S'W(rh)T'(rh), rather than by the temperature slope alone. For the five-dimensional charged regular AdS black hole in quasi-topological gravity, SW remains monotonic on the physical branch, so the usual temperature-slope rule is recovered only as a special consequence. The same off-shell structure also gives the local A3 cusp normal form near criticality, yielding the mean-field 1/2 branch separation exponent and explaining why smooth nondegenerate observables, such as the Lyapunov exponent, inherit the same scaling. In Lovelock black holes, S'W can change sign on non-planar branches, reversing the temperature slope stability assignment. However, on ghost-free and branch-regular Lovelock exteriors S'W remains positive. Thus the off-shell Hessian criterion also diagnoses why the ordinary slope rule is protected on physically admissible black holes branches.