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[3] ai.viXra.org:2508.0021 [pdf] submitted on 2025-08-09 10:05:22
Authors: Carl Littmann
Comments: 8 Pages.
Einstein’s Relativity Theory emphasizes that "if a body radiates a given amount of Energy, thatemitting body loses a Mass equal to that emitted Energy divided by the speed of light squared".But if that lost mass can’t be fully found by adding up all the resulting products, includingnegligible-mass high-energy Neutrinos; where did that mass go? My paper asserts that the lost(hidden) mass was ‘injected’ into the ‘aether’, increasing aether’s mass. As Einstein even said, in1930, "Space is Eating-Up matter!" I use that "Einstein Statement" to estimate a minimummass density of aether in Space, i.e., a key estimate but still likely much too low. And I alsoshow that Neutrino propagation is likely an Ethereal Pulse or Stress, like a Twisting SpringPulse (wave), instead of a forward or backward pulse. Thus, not likely a Particle mass flyingthrough space, like a bullet or ‘baseball’. And I give more details, and address related questions.
Category: High Energy Particle Physics
[2] ai.viXra.org:2508.0017 [pdf] submitted on 2025-08-08 02:03:38
Authors: Michael Durkay
Comments: 3 Pages. Co-developed with AI assistance
We propose Go, a conserved entropy-like parameter capturing self-regulating order in neutrino oscillations within the quantum vacuum, defined as Go =− i,jP(νi →νj) ln P(νi →νj), bounded by ln 3 ≈1.1 for maximal mixing under PMNS unitarity. As a hypothesis, it predicts a 5% enhancement in νµ →νe oscillation probability in cosmic voids via a fluctuation term δP ≈0.05 ×∆ρvac ρcrit , testable with Hyper-Kamiokande, JUNO, DUNE, KM3NeT, IceCube, and Super-Kamiokande. Grounded in empirical data, Go models pre-Big Bang void energy as an alternative to inflation, influencing CMB anisotropies. Limitations are acknowledged, with GLoBES simulations proposed for validation. A syllabus enhances accessibility, with brief historical reflections maintaining empirical focus.
Category: High Energy Particle Physics
[1] ai.viXra.org:2508.0007 [pdf] submitted on 2025-08-03 04:41:19
Authors: Hacı Soğukpınar
Comments: 16 Pages.
This study introduces a novel theoretical framework in which all fundamental structures of matter and interaction emerge from the self-organized, fractal resonances of two foundational quantum fields: a scalar energy field (Φ) and a vectorial charge field (Ψ). Unlike traditional particle physics models, this approach does not treat quarks, leptons, or gauge bosons as physical entities but as resonance nodes—zero-volume, massless quantized configurations of energy and charge—localized within a scale dependent fractal space-time geometry (D ≈ 2.7). These quantized field singularities form through the nonlinear intersections of Φ and Ψ fields, with no need for mediators such as gluons or a Higgs boson.The four known fundamental forces are unified under this framework as distinct manifestations of energy-charge field topology: the strong interaction arises from the fractal confinement of energy resonances (Φ); electromagnetism from the propagating wave modes of charge fields (Ψ); the weak interaction as topological phase transitions between coupled field domains; and gravity as a nonlocal curvature effect due to fractal field preservation. The model predicts a generalized gravitational potential of the form ��(��) ∼ 1/��(��—1), offering testable deviations from Newtonian gravity at microscopic scales. It also provides reinterpretations of dark matter as high-order, non-radiating Φ-field structures, and of proton spin as a result of internal fractal resonance dynamics. Leptons are not elementary, but arise as secondary energy-charge standing waves coupled to quark-like field nodes, while neutrinos appear as phase-neutral oscillatory modes with minimal interaction cross-sections. The theory addresses long-standing challenges in fundamental physics—such as the hierarchy problem, the origin of mass, and quantum gravity—by reducing all physical observables to the geometry and topology of unified fractal fields. Experimental implications include modified beta decay spectra, LHC resonance deviations, and precision gravitational measurements below millimeter scales.
Category: High Energy Particle Physics