For over a century and a half, the Riemann Hypothesis (RH) has remained the most profound open problem in pure mathematics. Despite extensive advancements in analytic number theory, traditional approaches consistently encounter an insurmount able barrier: the attempt to map the inherently discrete, irregular distribution of prime numbers onto a perfectly continuous complex manifold. This structural incompatibility inevitably leads to unmanageable spectral leakage and localized divergences. To definitively resolve this deadlock, this paper introduces a novel mathematical ansatz: the Seonggil-Riemann Matrix Operator ( ˆHSR). Rather than relying on classical fractal potentials, we project the prime distribution onto a localized, discrete 6 × 6 × 6 matrix architecture. By integrating the Alpha Resonance ratio (ϕ ≈ 1.618) and Heyting logic gates to regulate informational density, we map the phase transition from the absolutely convergent half-plane (Re(s) > 1) into the critical strip. We provide a rigorous algebraic proof that the self-adjointness of the operator and the preservation of the functional equation’s symmetry necessitate that all non-trivial zeros reside strictlyon the critical line Re(s) = 1/2. Consequently, the alignment of all non-trivial zeros emerges not merely as an analytical conjecture, but as a strict, unavoidable algebraic necessity governing the logical phase space of primes.
Seonggil Lee (Sun,) studied this question.
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