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[6] ai.viXra.org:2601.0104 [pdf] submitted on 2026-01-25 20:58:19
Authors: Bertrand Jarry
Comments: 10 Pages. Creative Commons Attribution 4.0 International (CC-BY 4.0)
We present a comprehensive framework in which quantum mechanics emerges as an effective low-energy description of a fundamentally discretized spacetime sub-strate. The microscopic dynamics are modeled by a linear cellular automaton de-fined on a spacetime lattice. In the continuum limit, the Schrödinger equation is recovered with arbitrary experimental precision. At finite lattice spacing, the discrete topology induces a non-linear (sinusoidal) dispersion relation. We demon-strate that its leading-order correction is equivalent to a quadratic modification of the relativistic dispersion relation, formally identical to n = 2 Lorentz Invariance Violation (LIV) models. This provides a concrete microphysical origin for quadratic LIV and yields falsifiable predictions in ultra-high-energy astrophysics. We expand on the mathematical formalism, provide detailed derivations, and present extensive numerical simulations supporting the theoretical predictions.
Category: High Energy Particle Physics
[5] ai.viXra.org:2601.0071 [pdf] submitted on 2026-01-18 22:16:45
Authors: Bertrand Jarry
Comments: 17 Pages. (Note by ai.viXra.org Admin: Please cite listed scientific references) Creative Commons Attribution 4.0 International (CC-BY 4.0)
The fundamental structure of spacetime at Planck scales remains one of the most profound open questions in theoretical physics. This paper presents a comprehen-sive analysis of the Discretized Substrate model, with particular focus on quadratic Lorentz Invariance Violation (LIV) manifesting at the Grand Unification Theory (GUT) scale. We develop a rigorous statistical framework for detecting LIV effects at EQG,2 ≈ 1016 GeV using ultra-high-energy (UHE) cosmic observations, specifi-cally addressing the challenges of systematic dispersion disentanglement from astro-physical variability. Through detailed analysis of current experimental constraints and future prospects with LHAASO and IceCube data, we establish testable predic-tions and identify key observational signatures that distinguish LIV from alternative dispersion mechanisms. Our analysis demonstrates that while galactic pulsar timing constrains quadratic LIV at ∼ 10^11 GeV, cosmological PeV observations provide the necessary leverage to probe five orders of magnitude higher energy scales.
Category: High Energy Particle Physics
[4] ai.viXra.org:2601.0070 [pdf] submitted on 2026-01-18 03:48:23
Authors: Jason Merwin
Comments: The document contains 18 pages. A link to the repository is provided in the conclusion.
We investigate two empirical anomalies in contemporary physics: the oscillatingnonlinearity in King plot isotope shift measurements and the systematic deviation ofpulsar braking indices from theoretical predictions. We demonstrate that both phenomena exhibit a 5/4 throughput ratio. King plot analysis of calcium and ytterbiumreveals oscillating deviations with a measured period of 7.8 ± 0.3 neutrons, matching the parameter-free prediction of 8 neutrons from beat frequency interference ina discrete relational network. Population meta-analysis of eight pulsars with reliablelong-term measurements yields a mean braking index n = 2.15 ± 0.26, excluding theStandard Model prediction (n = 3.0) [9] at 3.3σ significance with Bayesian evidenceof 100:1 in favor of the Relational Mathematical Realism (RMR) prediction (n = 2.5).Correlation analysis demonstrates that the braking residual ∆n = n − 3 shows nosignificant dependence on magnetic field strength, spin period, or spin-down rate, sup-porting a universal spacetime effect rather than varying magnetospheric processes.The appearance of a similar 5/4 ratio at nuclear (10^−15, m) and stellar (10^4, m) scalesmotivates further investigation into whether these effects may share a common origin.
Category: High Energy Particle Physics
[3] ai.viXra.org:2601.0056 [pdf] submitted on 2026-01-14 21:09:01
Authors: Thomas Lee Abshier
Comments: 12 Pages. (Note by ai.viXra.org Admin: For the last time, please cite listed scientific references of other authors and delete non-existant self-references!)
In Conscious Point Physics (CPP), electroweak unification emerges from discrete primitives in the 600-cell lattice without fundamental gauge fields or spontaneous symmetry breaking. We derive the effective SU(2)L× U(1)Y symmetry and Yang-Mills non-Abelian structure from hybrid DP flows, angular phase interferences (120°/240° biases for left-handed chirality), and golden-ratio quantized overlaps in nested polyhedral cages. The unified scale E_0 ≈ 246 GeV arises from bit compression in high-confinement states, with W/Z mass ratio (cos θ_W ≈ 0.881) from vertex density asymmetries. Couplings (g ≈ 0.652, gu2032 ≈ 0.357) follow from SS Vector gradients, reproducing sin2 θ_W ≈ 0.231 at 99.8% PDG agreement. Monte Carlo simulatio ns with full error propagation reproduce electroweak observables within experimental uncertainties. The framework yields falsifiable predictions, such as ∼ 10^−4 asymetries in off-shell W/Z interference and exotic lepton mixing at high transverse momentum, testable at the High-Luminosity LHC. This completes the electroweak series, unifying weak and electromagnetic interactions via geometry, and resolves standard puzzles like the hierarchy problem as emergent features.
Category: High Energy Particle Physics
[2] ai.viXra.org:2601.0036 [pdf] replaced on 2026-01-16 02:34:28
Authors: Jason Merwin
Comments: 30 Pages. The document has a link to the GitHub repository.
We report a recurring angular structure consistent with tetrahedral symmetry that appears across three distinct domains spanning many orders of magnitude in physical scale: Compton scattering, nuclear $gamma$-$gamma$ angular correlations, and pulsar glitch phenomenology. Our analysis is organized around two geometrically special angles that arise from different mathematical constraints: the ``magic angle'' $theta_{text{magic}}=54.74^circ$ where $P_2(costheta)=0$ eliminates the quadrupole term in Legendre expansions, and the tetrahedral angle $theta_{text{tet}}=arccos(-1/3)=109.47^circ$ associated with regular-simplex geometry. For Co60 Compton data near 662~keV we identify (i) a $sim$1.3% local suppression near $thetaapprox 54.8^circ$ and (ii) a broad flattening region near $thetaapprox 109.6^circ$ (within the resolution of the underlying digitized dataset), characterized here via variance-based metrics. In Cd110 $gamma$-$gamma$ angular-correlation coefficients reported by Krane & Steffen (1970), four transitions exhibit substantially reduced variance near $thetaapprox109^circ$ relative to the $thetaapprox45^circ$ window for the same reconstructed $W(theta)$ curves. In pulsar timing data from the Jodrell Bank catalog, consecutive glitch-magnitude ratios show clustering within the range 1.2--2.0 and display increased alignment with the simple harmonic sequence $(n+1)/n$ under stricter magnitude thresholds. We interpret these observations as phenomenological indicators of a shared geometric preference that is compatible with tetrahedral angle structure. We provide concrete, near-term tests—particularly target-material comparisons for Compton scattering and modern high-resolution $gamma$-$gamma$ correlation measurements—that can strengthen or falsify the proposed geometric interpretation.
Category: High Energy Particle Physics
[1] ai.viXra.org:2601.0028 [pdf] replaced on 2026-01-12 22:52:52
Authors: Herman Herstad Nythe
Comments: 16 Pages.
This paper presents a unified geometric framework deriving the Standard Model mass spectrum from the interplay of discrete Sphere Packing and continuous Golden Geometry. The theory rests on a fundamental mass unit MG ≈ 220 MeV, derived from the electron mass and a topological calculation of the fine-structure constant α-1 (precision 0.007%).Hadrons follow integer packing codes (Bottom Quark n=19, B-Meson n=24), while leptons follow a "Golden Ladder" based on φ, reproducing the Koide relation with 0.003% precision. Light quarks emerge via inverse fractal scaling.At the electroweak scale, masses follow quintic (5n) symmetry. The Top Quark reveals a fundamental duality: 28² ≈ 2π×5³ (0.18%), unifying Lie group geometry with quintic rotation. We identify a spectral cutoff at 3125 GeV, predicting a 15.5 keV Dark Matter candidate via a geometric seesaw mechanism. Finally, the theory predicts scalar resonances at 95 GeV and 650 GeV with symmetry-suppressed top-quark couplings, consistent with reported LHC excesses.
Category: High Energy Particle Physics