Entropy additivity from exponential decay of correlations: a coarse-grained operator approach

Abstract

Thermodynamic extensivity is commonly introduced as a postulate -- the homogeneity of degree one in thermodynamic potentials. We provide a constructive derivation of this property from microscopic conditions on the pair potential, without assuming it. Working with the one- and two-particle reduced densities of the N-body canonical Gibbs state, we introduce a combined coarse-graining operator C on single-particle phase space M=Λ×R3, producing dimensionless mesoscopic probabilities over spatial--momentum cells \Vi×Πα\. Under three conditions on the pair potential -- stability, temperedness, and exponential cluster decomposition with correlation length ξ -- we show, using the Ursell cluster expansion, that the coarse-grained entropy satisfies \[SCG=Σi Si+O\!(|Λ|de-/ξ),\] where ξ is the cell diameter. The correction is exponentially suppressed per cell, making entropy additive and recovering the thermodynamic limit of Ruelle and Fisher in explicit operator language. For systems with long-range interactions, where temperedness fails, the correction does not vanish, and non-additivity is quantified through inter-cell mutual information. We further show that spatial averaging does not commute with nonlinear thermodynamic functionals such as the entropy density -- a thermodynamic analogue of the cosmological averaging problem -- and we derive the generalised Euler relation with explicit surface corrections.