Nonadditivity in Quantum Field Theory: Replica Energies, Scaling Filters, and the Renormalization Group

Abstract

Extensive systems have a simple thermodynamic signature: the logarithm of the partition function scales homogeneously with the size of the system. We show that the failure of this scaling, measured by the replica energy E, provides a useful bridge between statistical mechanics and quantum field theory. The associated differential operator (1-1d L∂L) removes the leading bulk contribution to W= Z and isolates the part that is sensitive to boundaries, topology, defects, long-range forces, or other sources of nonadditivity. In quantum field theory this thermodynamic idea has two closely related uses. For ordinary finite-volume or spherical partition functions, suitable higher-order versions of the same filter remove local counterterms and extract universal fixed-point data such as the central charge, the sphere free energy F, and the Euler anomaly coefficient a. For replica geometries with entangling defects, the same filtering principle gives the renormalized defect free energy. In 2+1 dimensions, its n1 limit is precisely the entropic F-function. We use this perspective to distinguish ordinary finite-size corrections, topology-dependent constants in gapped phases, subextensive fracton degeneracies, and genuinely nonextensive systems with long-range interactions such as self-gravitating thermal matter. Replica energy therefore offers a common thermodynamic language for additivity, defect free energies, and renormalization-group irreversibility.