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The study aims to derive nuclear stability from a geometric interpretation of the strong nuclear force without using additional constants.

March 28, 2026Open Access

Geometric Origin of the Strong Nuclear Force: Lattice Pinning Strength and the Iron Stability Peak

Key Points

The study aims to derive nuclear stability from a geometric interpretation of the strong nuclear force without using additional constants.
Derived stability scale using Kim's Isotropic Template
Analyzed lattice pinning strength as a topological effect
Conducted numerical analysis to find Lattice Pinning Strength of approximately 7.93 MeV
Found Lattice Pinning Strength correlates with empirical energy per nucleon
Identified maximum Lattice Pinning Strength at iron-56
Provided geometric explanation for the iron stability peak and resolved the Strong CP problem

Abstract

We derive the nuclear stability scale directly from Kim's Isotropic Template (KIT) without any independent coupling constants. The strong nuclear force is interpreted as a topological "lattice pinning" effect, where nucleons are trapped in potential wells formed by the trivial zeros of the Riemann zeta function. Our numerical analysis yields a Lattice Pinning Strength (S₋₏) of approximately 7. 93 MeV, matching the empirical energy per nucleon. We further demonstrate that S₋₏ reaches its absolute maximum at ^56Fe, providing a parameter-free geometric explanation for the iron stability peak and a resolution to the Strong CP problem via real-axis phase-locking.

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Cite This Study

YilWook Kim (Thu,) studied this question.

synapsesocial.com/papers/69c772d98bbfbc51511e348c https://doi.org/https://doi.org/10.5281/zenodo.19231050

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