Extended Thermodynamics and Renyi Entropy Beyond Fixed Central Charge

Abstract

An outstanding problem in the framework of conformal thermodynamics concerns the interpretation of variations in the central charge C. In this paper, we construct a novel central-charge Rényi entropy via the Casini-Huerta-Myers (CHM) map by considering thermal CFTs on a hyperbolic cylinder within a fixed charge, field theory volume and central charge potential (Q,V,μC) grand canonical ensemble. We demonstrate that the resulting entropy satisfies all four fundamental Rényi entropy inequalities throughout the admissible range of μC, establishing its consistency as a genuine Rényi measure. Physically, this novel measure extends conventional Rényi entropy by capturing the degree of entanglement across a statistical ensemble of holographic CFTs with fluctuating degrees of freedom. Furthermore, our conformal thermodynamic analysis of near-extremal configurations reveals that residual entropy arises from the central charge sector rather than thermal excitations. The mass gap that separates the extremal state and the first thermal excitation introduces a characteristic temperature scale T*, which translates via the CHM map into a distinguished characteristic Rényi index n*. Crucially, we propose that n* separates the theory space into two qualitatively distinct statistical regimes: a dominant-theory regime (n > n*) governed by the most probable CFT realizations, and a multi-theory regime (n < n*) where a broader spectrum of fluctuating theories and higher-energy modular excitations becomes increasingly relevant.