Published January 29, 2026
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Genesis of Matter: Topological Assembly of the Hydrogen Atom and the Resonance Migration in the Kelvin Lattice.
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Description
This paper presents a fundamental shift from classical particle physics to the paradigm of Information Modulation. We define matter not as a substance, but as a localized inertia of an information wave captured within a topological lattice. By utilizing the Kelvin cell (tetrakaidecahedron) as the primary unit of space-time, this work demonstrates that mass and physical constants are emergent properties of geometric resonances governed by the invariant Phi = 5.3146.
Key Scientific Contributions:
- Topological Baryogenesis: The discovery of the "Protonic Octet" — a super-stable cluster of 8 Kelvin cells forming the hydrogen nucleus at the 938.272 MeV resonance.
- Information Viscosity: A mathematical derivation of mass as the lattice's resistance to wave propagation through the faces of the tetrakaidecahedron.
- Resonance Migration Theory: A new definition of motion as the sequential transfer of the Phi-state between adjacent cells, providing a geometric basis for inertia, kinetic energy, and relativistic effects.
- Unified Resonance Spectrum: A complete periodic table of resonances, predicting high-energy locking nodes at 2.6, 126, 180, and 240 GeV.
- Dark Matter Identity: Classification of "Inertial Solitons" (Omega-Phi) as self-locked, non-radiating topological nodes within the lattice.
Methodology:
The theoretical framework was verified through computational synthesis and frequency modulation, confirming the spontaneous self-organization of stable atomic structures when the lattice is driven by the Phi-invariant.
The theoretical framework was verified through computational synthesis and frequency modulation, confirming the spontaneous self-organization of stable atomic structures when the lattice is driven by the Phi-invariant.
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Additional details
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