In this paper we construct a foundational 3-dimensional geometric manifold and topological framework for strictly bounding the non-trivial zeros of the Riemann zeta function, ζ(s), exclusively to the critical line R(s) = 1/2 . By deriving a fundamental resting angle from the Euler-Mascheroni constant and establishing a logarithmic boundary curve utilizing the dimensional projection of circle geometry, we construct a continuous macroscopic phase space. This isolates the non-linear, logarithmic parametric arc length of the curve ζ(1/2 + it). Furthermore, by applying Pythagorean conservation of tension to this space, we derive the “Sigma Isolator,” extracting the real part σ purely via geometric strain. By applying Riemann’s functional equation and the Argument Principle to this strictly budgeted topological envelope, we introduce a proof by contradiction, demonstrating that off-line zero doublets demand a geometric “Orbit Toll” that shatters established amplitude bounds. Exploring the interlinked nature of primes and zeros reveals that plotting prime numbers as imaginary altitude coordinates generates a contiguous Pythagorean chain—a logarithmic Spiral of Theodorus. We prove that the telescoping conservation of this prime spiral creates an impenetrable asymptotic wall (dZ/dθ→0), which, when evaluated against Riemann’s Explicit Formula and the mechanics of Arc Length Starvation, analytically forbids zero deviation. The theoretical “Damping Field” of this geometry is empirically verified out to the 103-billionth zero via a dual-engine computational suite.
Anthony John Kerr (Tue,) studied this question.