Endpoint Control of Thermodynamic Topological Classes for Fixed Charge dd-dimensional Reissner--Nordström Black Holes in a Cavity

Abstract

We study thermodynamic topological classes of d-dimensional Reissner--Nordström (RN) black holes in a cavity at fixed charge. Starting from the reduced Euclidean action, we use the quasilocal energy, entropy, and on-shell inverse temperature to construct the off-shell vector field. A finite cavity gives two charge dependent classes: neutral black holes belong to W0-, whereas charged black holes belong to W1+. If the cavity radius is sent to infinity at fixed physical charge, the endpoint data change, giving W1- for the neutral case and W0+ for the charged case. Thus the electric charge and the outer boundary, rather than the spacetime dimension in the explicit four- and five-dimensional examples, determine the refined topological class within this RN cavity family.