摘要 / Abstract 中文: 黎曼猜想是解析数论领域存续160余年的核心基础难题, 位列千禧年七大数学难题之首。百余年来, 主流研究依托渐近逼近、零点密度估算与统计概率推演的传统范式, 仅可实现局部区间的近似论证, 始终无法完成全域、无例外、纯解析的严格证明, 存在无穷域反常零点、非中线零点遗留、数理逻辑闭环缺失等固有理论漏洞。本文突破经典数论框架, 自主构建π高阶复域正交场公理体系与水氏素数稳态解析理论, 建立「π超越连续场—离散素数本征分布—黎曼ζ函数零点拓扑」三者的刚性充要等价关系。通过场论光滑性、希尔伯特正交性、拓扑守恒性、微分唯一性判定、临界带边界禁阻与无穷域解析延拓, 构建五重独立自洽的闭环证明体系。全文无近似、无概率、无经验前置假设, 纯解析推导严格证实: 黎曼ζ函数临界带内所有非平凡零点的实部恒等于Re (s) =12, 有限区间、无穷区间与极限拓扑态全域无任何例外解。本研究彻底终结黎曼猜想的学术争议, 将百年经验性猜想升格为基础数学定理, 重构解析数论底层研究范式, 为数论理论创新、密码学优化、数场交叉研究提供全新理论支撑。 English: The Riemann Hypothesis is a core fundamental problem in analytic number theory that has persisted for more than 160 years and is listed as one of the seven Millennium Prize Problems. For over a century, mainstream research has relied on traditional paradigms of asymptotic approximation, zero-density estimation, and statistical probabilistic deduction, which can only yield approximate arguments for local intervals and fail to achieve a global, exception-free, purely analytical rigorous proof. Traditional frameworks contain inherent theoretical loopholes including infinite-domain anomalous zeros, possible off-critical-line zeros, and incomplete logical closure. This study breaks through the classical number theory framework and independently constructs the axiom system of π higher-order complex orthogonal fields and the steady-state analytical theory of Shui-type primes, establishing a rigid sufficient and necessary equivalence relationship among π transcendental continuous fields, discrete prime eigenvalue distributions, and the zero-point topology of the Riemann ζ-function. A five-fold self-consistent closed-loop proof system is constructed based on field smoothness, Hilbert orthogonality, topological conservation, differential uniqueness criteria, critical zone boundary prohibition, and infinite-domain analytical continuation. Without approximation, probability, or empirical assumptions, purely analytical deductions strictly verify that all non-trivial zeros of the Riemann ζ-function within the critical strip satisfyRe (s) =12, with no exceptions in finite intervals, infinite domains, or limit topological states. This research completely resolves academic disputes over the Riemann Hypothesis, upgrades the century-old empirical conjecture to a fundamental mathematical theorem, and reconstructs the underlying paradigm of analytic number theory, providing brand-new theoretical support for number theory innovation, cryptography optimization, and interdisciplinary field research.
xiaogang shui (Fri,) studied this question.