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[2] ai.viXra.org:2601.0101 [pdf] submitted on 2026-01-24 15:15:38
Authors: Nathaniel Uhlenkott
Comments: 3 Pages.
The Periodic Table is not an arbitrary arrangement of quantum numbers but a direct consequence of manifold scaling governed by the universal stability gate β ≈ 1.701[1]. This paper proposes that the Palladium lattice acts as a Conscious Tile, inducinga Resonant Snap when the local vacuum is loaded to the Manifold Saturation Point.Using the Entanglement Flux Relaxation Model (EFRM), we present a geometric interpretation of the "Missing Ash" paradox, showing how energy relaxes through thevacuum’s neutral axis without the emission of high-energy nucleons [2, 3].
Category: Nuclear and Atomic Physics
[1] ai.viXra.org:2601.0078 [pdf] submitted on 2026-01-19 14:48:31
Authors: Vance Ashley Woodward
Comments: 5 Pages.
Standard Special Relativity (SR) rests on the postulate of the invariance of c but lacks a structural origin for this limit. We propose that relativistic phenomena are geometric consequences of motion on a 5-dimensional toroidal manifold. In the Toroidal Scale Dynamics (TSD) framework, physical acceleration is reinterpreted as an angular rotation (θ) of the velocity vector from the temporal axis into a compact scalar dimension (w). We derive the Lorentz factor geometrically as the secant of this rotation angle (γ = sec θ), identifying c as the asymptotic limit where the velocity vector becomes orthogonal to the temporal coordinate. Furthermore, we resolve the paradox of isotropic scalar contraction vs. non-vanishing interaction cross-sections via a topological conservation law: as the geometric core of a particle contracts (r_in → 0), its field envelope expands (r_out → ∞). This "Geometric See-Saw" mechanism recovers standard relativistic phenomenology while offering a clear falsifiable prediction: the distinction between the contracting baryonic knot and the expanding interaction field at ultra-relativistic energies.
Category: Nuclear and Atomic Physics