Zeta-Minimizer Theorem: Variational Emergence of Primes, Zeta, and Stratified Geometries from Helical Optimization in Measure Spaces

The Zeta-Minimizer Theorem formalizes the minimization of a phase functional derived from compressibility factor expansions and exponential resummations, yielding convergence to the Riemann zeta function ζ(s). In a symmetric measure space (X’μ’G)equipped with helical operators, constraints of rational signed cosines, positive integer representation dimensions, non-zero integer differences, and prime-modulated exponential decays ensure prime emergence as indivisible cycles in representation graphs (via Hilbert’s irreducibility and Maschke’s theorem). Corollaries derive stacked phases as stratified orbifolds with hyperbolic tendencies, emergent geometries as layered manifolds, bounded prime descent, dimensional resistance, and RH equivalence via spectral centering at Re(s)=1/2. Axioms abstract thermodynamic intuitions purely: Axiom I as concave entropy maximization on measures; Axiom II as spectral Gibbs minima with explicit frequency forms; Axiom III as covariance projections and flux conservation. The framework generates number-theoretic structures as shadows of optimization processes, with complex numbers/polynomials as projected artifacts and quantization implicit in multiphase triads. Applications include atomic stratification (quantized shells from phase jumps), angular momentum tensors (minimized over strata), fine structure invariant (α ̂^(-1)=4π^3+π^2+π≈137.036 from cycle sums with β=5leaps), and covariant mappings to arbitrary variables via category theory (functors and RG universality for Gear discretization). This provides rigorous heuristics for analytic number theory, algebraic geometry, and spectral theory, demoting elementary constructs to derived descriptions.