This paper breaks away from the traditional macroscopic perspective that relies on global analytic continuation in the study of the distribution of zeros of the Riemann zeta function. Instead, it proposes a bottom-up, microscopic analytic framework that reveals the algebraic and analytic origins of the special status of the critical line =1/2. The innovations and core contributions of this paper are as follows. First, by extracting a local characteristic function Sₚ (s) from the Euler product, we prove on a purely algebraic level that the critical line is the unique "analytic stationary surface" (as defined in this paper) where the moduli of all local channels are decoupled from the imaginary part. Second, using the polar form of the Cauchy-Riemann equations, we rigorously prove that any deviation from the critical line necessarily induces a non-zero transverse gradient of the argument, a phenomenon we term "symmetry breaking. " On this basis, via Fourier series expansion and the orthogonality of prime frequencies, we precisely calculate that the long-time mean-square energy of the truncated relative gradient field exhibits unbounded power-law divergence away from the critical line. To address the distribution of zeros, we employ a *reductio ad absurdum* argument to rigorously exclude pure L² energy quota models based on the truncated background field, clarifying the intrinsic limitations of this approach. We then focus our attention on the critical line, where the energy divergence is completely suppressed. We define a global microscopic phase detection kernel K (t) = Re ('/) and explicitly utilize its analytic property of eliminating pole singularities to remain finite at the zeros. We establish its exact duality with the derivative of the Riemann-Siegel theta function, K (t) = -' (t). We derive a rigorous "zero phase integral quota law, " K (t) dt = - + Sₙ, which reconstructs the classical Riemann-von Mangoldt formula for the mean spacing of zeros from a novel microscopic phase evolution perspective. Furthermore, we provide a deterministic interpretation of the zero repulsion effect based on the coherent interference of prime frequencies, arguing that repulsion stems not from an energy barrier, but from the interference difficulty for the microscopic phase kernel to fulfill a fixed quota within a finite interval. It should be noted that this paper does not prove the Riemann Hypothesis; it merely offers a new interpretation of the microscopic mechanisms on the critical line. This work grounds the statistical phenomenon of zero distribution in the microscopic structure of primes, providing new theoretical tools and physical insights for analytic number theory.
Ni Chuangao (Wed,) studied this question.