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Zenodo
2025
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| Online Access: | https://doi.org/10.5281/zenodo.16873504 |
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Table of Contents:
- <p><strong>Theory of Time — Antimatter, Phase-Shifted Photons in S³, and Experimental Correspondence Framework</strong></p> <p><strong>Author:</strong><br>Luis Morató de Dalmases</p> <p><strong><strong>Files</strong>:</strong></p> <p><br>1. Annex A — Antimatter ≡ Non-Collapsing.pdf</p> <p>2. Annex B — Complete Hamiltonian in S3 for.pdf</p> <p>3. Annex C — Correspondence between Antimatter.pdf</p> <p>4. Annex D — Formal Proofs of Theorem D.1.pdf</p> <p>5. Annex E — Experimental Validation, Calibration.pdf</p> <p><strong>Abstract:</strong><br>This work presents a unified theoretical and experimental framework within the <em>Theory of Time</em> (LT) for describing the correspondence between antimatter, phase-shifted photons in the 3-sphere (S³), and their measurable physical parameters. Antimatter is interpreted as <em>non-collapsing vibrations</em> encoded in prime numbers, providing a stable mathematical and physical representation within the LT lattice. Phase-shifted photons in S³ are modeled through a complete Hamiltonian formulation adapted to temporal-spatial curvature, ensuring compatibility with both Dirac–LT and plasma/optical scaling.</p> <p>A <strong>Correspondence Theorem</strong> is established, mapping <em>topological confinement</em> geometries (Möbius, Toroidal, Helicoidal, Hopf Knot, Conway Knot, Multi-Layer Cavities, Discrete Lattices) to an LT triplet <span><span>(δϕBCH,Φ□,δv)(\delta\phi_{BCH}, \Phi_\square, \delta v)</span><span><span><span>(</span><span>δ</span><span><span>ϕ</span><span><span><span><span><span><span><span>BC</span><span>H</span></span></span></span><span></span></span></span></span></span><span>,</span><span>Φ<span><span><span><span><span><span>□</span></span></span><span></span></span></span></span></span><span>,</span><span>δ</span><span>v</span><span>)</span></span></span></span>, the associated Hamiltonian, Q-factor requirements, and experimental tolerances. Formal proofs confirm the robustness of the mapping for both matter and antimatter sectors, including directional dark matter and low-interaction topologies.</p> <p>The work concludes with an <strong>Experimental Validation Protocol</strong> specifying calibration methods, phase measurement techniques, and synchronization strategies for space–time resonance stability. This ensures the transition from theoretical constructs to practical implementation in quantum energy systems, particle confinement, and potential faster-than-light navigation scenarios.</p> <p><strong>Keywords:</strong><br>Theory of Time, Temporal Lattice, Antimatter, Prime Number Encoding, Phase-Shifted Photons, S³, Topological Confinement, Hamiltonian Scaling, Quantum Resonance, Experimental Protocols, Dark Matter Models, Navigation in Space–Time.</p> <p><strong>License</strong>: Creative Commons Attribution 4.0 (CC-BY 4.0) <span lang="EN-US">(Attribution - NonCommercial - ShareAlike)</span></p>