Part II of the Negentropy, Closure Degeneracy, and Entropy Topologies Series Central IdentitySC (c) =kC log OmegaC (c) Entropy is the logarithmic measure of closure-preserving relational degeneracy. Closure Degeneracy | Paper II of the Negentropy, Closure Degeneracy, and Entropy Topologies SeriesThis paper formalizes the conceptual insight developed in Paper 1: entropy is not fundamental disorder, but epistemic access to closure-topological multiplicity. The present paper gives that claim mathematical form by defining entropy as the logarithmic measure of closure degeneracy. A relational configuration space R provides the domain of possible configurations. A closure functional Cphi assigns closure cost. Constant-cost configurations form closure shells Sigmac. The measure of such shells defines closure degeneracy OmegaC (c). Entropy is then: SC (c) =kC log OmegaC (c). This formal identity generalizes Boltzmann's degeneracy principle while relocating its origin from macrostate-compatible microstates to closure-preserving relational configurations. Probability distributions, thermodynamic entropy, Shannon entropy, and quantum entropy are preserved as projected or specialized forms of closure degeneracy. The central contribution is therefore: Entropy is the logarithmic measure of closure-preserving relational degeneracy. The first paper in this series argued that negentropy is ontological correlation capacity, entropy topology is relational closure accessibility, and entropy is epistemic measurement of accessible degeneracy. The present paper formalizes that claim. We introduce a relational configuration space R, whose elements phi in R represent possible relational configurations of a system. A closure functional Cphi assigns a closure cost to each configuration, measuring deviation from relational closure. For each closure-cost value c, the functional defines a closure shell: Sigmac = phi in R | Cphi = c. The measure of this shell defines closure degeneracy: OmegaC (c) =mu (Sigmac). Closure entropy is then defined as: SC (c) =kC log OmegaC (c). This formulation shifts the origin of entropy from probability space to closure-functional geometry. Probability distributions and measured entropies remain valid, but they arise after projection from a deeper relational structure. Entropy is not introduced as disorder, ignorance, or a primitive statistical assumption. It emerges from the multiplicity of relational configurations that preserve closure under constraint. The paper develops projection consistency, the closure-entropy correspondence theorem, entropy topology from closure level sets, closure partition functionals, mean closure cost, Legendre duality between closure cost and entropy, and recovery of standard entropy forms in thermodynamic, information-theoretic, and quantum contexts. The result is a variational foundation for entropy as closure-preserving relational multiplicity. Closure Degeneracy | Paper II of the Negentropy, Closure Degeneracy, and Entropy Topologies Series KeywordsClosure degeneracy; closure entropy; relational configuration space; closure functional; entropy topology; variational entropy; closure cost; relational microstates; projected entropy; coarse-graining; entropy as log measure; thermodynamic information; closure shell; Legendre duality; closure partition functional; closure topology.
Philip Lilien (Tue,) studied this question.
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