Trinity of Varentropy: Finiteness, Fluctuations, and Stability in Power-Law Statistics
Abstract
Power-law distributions are widely observed in complex systems, yet establishing their thermodynamic consistency remains a theoretical challenge. In this paper, we present a thermodynamic framework for power-law statistics based on the renormalized entropy s2-q. Derived from the asymptotic scaling of the combinatorial q-factorial, this quantity yields a stable thermodynamic limit, remaining finite (O(N0)) for systems with strong correlations. Furthermore, we clarify the physical origin of the nonlinearity parameter q through the concept of Varentropy (Variance of Entropy). By unifying the macroscopic variational principle with the microscopic Superstatistics framework, we derive the relation |q-1| 1/C, where C is the heat capacity of the reservoir. This result suggests that power-law statistics provides a thermodynamic description of finite systems, where the finite heat capacity of the heat bath necessitates a generalization beyond the standard Boltzmann-Gibbs limit (C ∞).
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