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Abstract
We introduce a geometric and spectral reformulation of the Riemann Hypothesis based on the analysis of a complex vector-valued function, the Function of Residual Oscillation (FOR(N)), defined by a regularized spectral sum over the nontrivial zeros of the Riemann zeta function. This function reveals a torsion structure in the complex plane that is minimized under the critical-line condition Re(ρ) = 1/2. By analyzing the directional stability of the associated vectors, we demonstrate that the Riemann Hypothesis is equivalent to the global vanishing of the spectral torsion function τ(N). The approach combines geodesic vector dynamics, coherence cancellation, and asymptotic convergence, providing a new structural perspective on one of the most fundamental problems in mathematics.
Supplementary weblinks
Title
Spectral Coherence and Geometric Reformulation of the Riemann Hypothesis via Torsion-Free Vector Waves
Description
This link leads to the author’s official website, where updated versions, interactive graphs, complementary appendices, technical commentary, and additional materials related to the spectral and geometric reformulation of the Riemann Hypothesis are available. The site serves as an extended repository featuring analytical illustrations, detailed footnotes, supplemental proofs, and cross-references to other major conjectures. It directly complements the main article, allowing readers to explore in real time the implications of the torsion-free vector wave model in the spectral and functional context, as well as track future updates to the work.
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