| ai.viXra.org > High Energy Particle Physics > 2507 |
|
 |
| ai.viXra.org > High Energy Particle Physics > 2507 |
|
|
[8] ai.viXra.org:2507.0136 [pdf] submitted on 2025-07-31 19:32:06
Authors: Hacı Soğukpınar
Comments: 17 Pages.
The standard ΛCDM model has been remarkably successful in explaining many features of the cosmos; however, it remains theoretically incomplete. Its reliance on a primordial singularity, the unexplained nature of dark energy, and its incompatibility with quantum gravity at Planck scales point to fundamental gaps in our understanding of the universe. This study proposes a holographic bubble universe framework as a viable alternative, addressing these limitations through a physically motivated and observationally testable model.In this approach, the universe is treated as a 3+1-dimensional bubble embedded in a higher-dimensional quantum medium. The model eliminates the need for an initial singularity by replacing it with a finite quantum fluctuation in a pre-geometric background. Cosmic expansion arises naturally from the negative pressure exerted by the external environment—mimicking dark energy dynamics without invoking a finely tuned cosmological constant. Moreover, the model integrates the holographic principle by encoding information on the 2+1D boundary, thereby preserving unitarity and resolving entropy paradoxes inherent in the standard model.The framework yields concrete, testable predictions: echoes and anisotropies in the Cosmic Microwave Background (CMB), discrete gravitational wave modes, and topological features in large-scale structure distributions. These signatures are consistent with recent data from DESI, LISA, and Euclid, offering a promising avenue to reconcile observational cosmology with quantum gravity. By addressing the foundational weaknesses of ΛCDM—particularly the singularity problem and the ad hoc treatment of dark energy—the bubble universe model offers a unified, falsifiable, and conceptually coherent cosmological paradigm.
Category: High Energy Particle Physics
[7] ai.viXra.org:2507.0129 [pdf] submitted on 2025-07-30 17:56:14
Authors: Michael Hirsch Tomasson
Comments: 20 Pages. 31 equations
The Higgs Mechanism, as formulated within the Standard Model of particle physics, has proven remarkably successful. It explains how electroweak symmetry breaking gives rise to massive vector bosons, maintains gauge invariance, and preserves unitarity in scattering amplitudes. Yet, outstanding questions remain. Why should a fundamental scalar field exist at all? Why does the electroweak vacuum select the observed configuration? A Symbolic Structure Field Theory (SSFT) was recently described that postulated an ontologically primary field structure with a binary scalar substrate field $psi_0$ with extensions $psi_1$, a scalar vector field, and $psi_2$, a fiber bundle section. While $C_8$ was used to map elementary particles, the Higgs Boson remains undefined in SSFT. Here, we extend symbolic field formalism to specifically define the Higgs Mechanism. A consistent mathematical formalism is proposed to allow refinement and empiric testing.
Category: High Energy Particle Physics
[6] ai.viXra.org:2507.0128 [pdf] submitted on 2025-07-29 04:40:31
Authors: Ivars Fabriciuss
Comments: 5 Pages.
We propose a geometric model of the electron based on its oscillation between ordinary three-dimensional real space $mathbb{R}^3$ and an imaginary quaternion space $mathcal{I}^3$. This transition, occurring at the Zitterbewegung frequency $omega_{m ZB} = frac{2 m c^2}{hbar}$, gives rise to a dynamic structure: a figure-8 loop in real space (with a total $2pi$ twist) and its inverted mirror loop in an imaginary space. The projection across a shared Planck-scale circular boundary (the emph{contact disc}) encodes both mass and charge, while the torsional stiffness of this contact region is identified as the physical origin of electron mass. We explore the unification of gravitational and electromagnetic length scales via this projection geometry and propose that the Schwarzschild radius $r_s$, Compton wavelength $lambda_C$, and an imaginary projection length $ell_infty$ are deeply related by real-to-imaginary space inversion. The resulting framework offers a consistent ontology for particle structure, field emergence, and vacuum coupling across dual phases of the physical universe.
Category: High Energy Particle Physics
[5] ai.viXra.org:2507.0075 [pdf] submitted on 2025-07-14 02:37:18
Authors: Paul E Lillington
Comments: 40 Pages.
We introduce a field-theoretic model in which particles are represented as spherical voids in the Higgs field, bounded by a resonant surface wave oscillating at a harmonic of the Planck frequency. A quantized standing wave condition leads to a surface node formula ��=2��������ℎ N=h2πRmc, from which charge is derived via a discrete scaling parameter ��=��/�� Z=N/k. Applying this to atomic nuclei yields predicted charges with sub-10% deviation across the periodic table. A field-modified Rayleigh—Plesset equation governs the dynamic behavior of the bubble radius, offering a real-space geometric alternative to intrinsic charge and quark confinement models. This framework provides a testable pathway for linking classical geometry and quantum-scale charge distribution.
Category: High Energy Particle Physics
[4] ai.viXra.org:2507.0050 [pdf] submitted on 2025-07-09 23:56:25
Authors: Ole Frithjof Grude
Comments: 3 Pages.
General relativity's prediction of singularities and reliance on exotic matter for wormholes revealgaps in our understanding of spacetime. The Grude Nmax Hypothesis, born from a ham radiooperator's wave-based perspective and expertise in electronics, introduces a scalar field, Nmax(~1.78e-17 eV, Compton wavelength ~0.465 AU), which limits curvature and causality as acomplement to the Higgs field. This hypothesis serves as a pointer to explore newpossibilities-preventing singularities, stabilizing wormholes, and regulating the speed of light-with testable predictions for black hole dynamics and AU-scale measurements.
Category: High Energy Particle Physics
[3] ai.viXra.org:2507.0047 [pdf] submitted on 2025-07-08 12:36:04
Authors: Evert van Brummelen
Comments: 4 Pages.
We present a compact analytical expression for the proton—electron mass ratio that centers on a core term (πα)^2, refined by a critical correction factor 27/28. This factor, strongly suggestive of quark—electron coupling, bridges the gap between the elegant core and the experimentally observed ratio. The resulting expression matches the CODATA value within 0.08%. Two additional refinements—classical self-energy and a rational residual term—further increase the accuracy, now reproducing all known experimental digits. This suggests that the proton—electron mass ratio may ultimately emerge from a structured interplay of known constants, rational factors, and discrete self-interaction effects.
Category: High Energy Particle Physics
[2] ai.viXra.org:2507.0043 [pdf] submitted on 2025-07-07 23:53:54
Authors: Anwar M. Quereshi
Comments: 5 Pages.
This paper proposes the Hidden Antimatter Bundling Theory, a novel hypothesis challenging the conventional separation of matter and antimatter. The theory suggests that antimatter is not absent from the observable universe but inherently bundled within matter in stable, deeply coupled structures. High-energy collisions may not create antimatter but instead separate these bundled configurations, revealing pre-existing antiparticles. Furthermore, this paper challenges the established notion of annihilation, proposing that matter-antimatter interactions involve the splitting and rebundling of fundamental components, not total destruction. This hypothesis offers an alternative explanation for the observed matter-antimatter asymmetry and suggests new experimental directions.
Category: High Energy Particle Physics
[1] ai.viXra.org:2507.0035 [pdf] submitted on 2025-07-06 03:29:35
Authors: Moninder Singh Modgil, Dnyandeo Dattatray Patil
Comments: 37 Pages.
This work presents a comprehensive theoretical framework that unifies key structural and dynamicalaspects of the Standard Model of particle physics through the lens of mirror textures andsemantic resolutions. We develop a hierarchy of scales encoded by textured delta distributions,δϵi , and their mirror duals, ℵi, which together define a geometric and algebraic infrastructurefor functional calculus and renormalization group flow. Each physical parameter—masses, mixingangles, couplings—is interpreted as emerging from contractions, projections, or interferencepatterns across textured layers of varying resolution. The framework reinterprets the structureof a point in field theory as a semantically layered entity, and extends naturally to non-Hausdorffspaces and branched vacua. We derive numerical estimates for fine-structure constants, fermionmasses, CKM and PMNS matrices, the QCD scale, and the strong CP phase, all from a commonscale-semantic formalism. This unification opens a pathway toward understanding physicalconstants and field behavior as emergent from categorical and semantic transformations acrossmirror-textured resolutions.
Category: High Energy Particle Physics