High Energy Particle Physics

1410 Submissions

[12] viXra:1410.0201 [pdf] submitted on 2014-10-30 05:54:06

Understanding the Balance of Matter and Antimatter in the Universe

Authors: George Rajna
Comments: 13 Pages.

Physicists in the College of Arts and Sciences have made important discoveries regarding Bs meson particles -- something that may explain why the universe contains more matter than antimatter. Named Ds3*(2860), the particle, a new type of meson, was discovered by analyzing data collected with the LHCb detector at CERN's Large Hadron Collider (LHC). The new particle is bound together in a similar way to protons. Due to this similarity, the Warwick researchers argue that scientists will now be able to study the particle to further understand strong interactions. Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[11] viXra:1410.0152 [pdf] submitted on 2014-10-23 22:12:24

The Eightfold Way Model, the Su(3)-Flavour Model and the Medium-Strong Interaction

Authors: Syed Afsar Abbas
Comments: Modern Physics Letters A Vol. 30, No. 12 (2015) 1550050 (9 pages) DOI: 10.1142/S0217732315500509

Lack of any baryon number in the Eightfold Way model, and its intrinsic presence in the SU(3)-flavour model, has been a puzzle since the genesis of these models in 1961-1964. In this paper we show that this is linked to the way that the adjoint representation is defined mathematically for a Lie algebra, and how it manifests itself as a physical representation. This forces us to distinguish between the global and the local charges and between the microscopic and the macroscopic models. As a bonus, a consistent understanding of the hitherto mysterious medium-strong interaction is achieved. We also gain a new perspective on how confinement arises in Quantum Chromodynamics.
Category: High Energy Particle Physics

[10] viXra:1410.0123 [pdf] submitted on 2014-10-21 13:34:44

The Seesaw Mechanism and the Structure of Spacetime above the Electroweak Scale

Authors: Ervin Goldfain
Comments: 8 Pages. Work in progress.

According to the seesaw mechanism, neutrino masses arise from the existence of heavy Majorana neutrinos postulated to emerge near the grand unification scale (GUT) of about 10^16 GeV. Despite its theoretical appeal, this scenario involves either physics at inaccessible scales or tuning the Yukawa couplings to un-naturally low values. Our work sidesteps the seesaw mechanism and shows that neutrino masses follow from placing the Standard Model on a spacetime support equipped with arbitrarily small deviations from four dimensions.
Category: High Energy Particle Physics

[9] viXra:1410.0100 [pdf] replaced on 2014-10-29 19:49:13

Baryon Asymmetry, Dark Matter, WIMP and Super Massive Black Holes

Authors: Jaidev B. Parmar
Comments: 4 Pages.

CPT theorem is reinterpreted in the context of commonly observed phenomenon of free neutron beta decay and extrapolated to explain the Baryogenesis in the early Universe that has led to the observed Baryon Asymmetry in the present Universe. Anti-neutron and Protonium are proposed as a suitable Dark Matter WIMP candidates. Anti-neutrons are proposed as the basic components from which Super Massive Black Holes (SMBH) at the Galactic centers are formed.
Category: High Energy Particle Physics

[8] viXra:1410.0099 [pdf] submitted on 2014-10-17 09:18:16

Realistic Quark-Gluon Plasma and the Electro-Strong Interaction

Authors: George Rajna
Comments: 13 Pages.

More realistic versions of lattice QCD may lead to a better understanding of how quarks formed hadrons in the early Universe. The resolution of the Proton Radius Puzzle is the diffraction pattern, giving another wavelength in case of muonic hydrogen oscillation for the proton than it is in case of normal hydrogen because of the different mass rate. Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[7] viXra:1410.0096 [pdf] submitted on 2014-10-17 09:23:03

New Subatomic Particle and the Electro-Strong and Weak Interaction

Authors: George Rajna
Comments: 11 Pages.

Named Ds3*(2860), the particle, a new type of meson, was discovered by analyzing data collected with the LHCb detector at CERN's Large Hadron Collider (LHC). The new particle is bound together in a similar way to protons. Due to this similarity, the Warwick researchers argue that scientists will now be able to study the particle to further understand strong interactions. Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[6] viXra:1410.0093 [pdf] submitted on 2014-10-17 09:13:13

The Challenge of the Lepton Universality

Authors: George Rajna
Comments: 13 Pages.

The finding that electrons and muons aren’t produced equally in certain particle decays may hint at a crack in the standard model. The resolution of the Proton Radius Puzzle is the diffraction pattern, giving another wavelength in case of muonic hydrogen oscillation for the proton than it is in case of normal hydrogen because of the different mass rate. Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[5] viXra:1410.0075 [pdf] submitted on 2014-10-14 14:32:23

Ultraviolet Completion of Electroweak Theory on Minimal Fractal Manifolds

Authors: Ervin Goldfain
Comments: 11 Pages. Work in progress

The experimental discovery of the Higgs boson at the Large Hadron Collider (LHC) has effectively disqualified all Higgs-less models developed prior to July 2012. Today, despite its conclusive validation, the Higgs sector of the Standard Model (SM) remains a largely uncharted territory. This raises the following question: Are there any hidden insights brought up by Higgs-less models that can still be beneficial for the on-going research in particle physics? Pursuing this thought, we re-examine here Moffat’s scenario based on a finite electroweak Lagrangian built outside the Higgs paradigm. Unlike the original proposal, we place the model on a spacetime support equipped with minimal fractality. In doing so, we find that the theory is perturbatively well-behaved at large scattering cross-sections and that it gracefully connects with the conventional formulation of the SM in the limit of vanishing fractality.
Category: High Energy Particle Physics

[4] viXra:1410.0058 [pdf] submitted on 2014-10-12 10:19:18

Existence of Antiparticles as an Indication of Finiteness of Nature

Authors: Felix M. Lev
Comments: 9 Pages.

It is shown that in a quantum theory over a Galois field, the famous Dirac's result about antiparticles is generalized such that a particle and its antiparticle are already combined at the level of irreducible representations of the symmetry algebra without assuming the existence of a local covariant equation. We argue that the very existence of antiparticles is a strong indication that nature is described by a finite field rather than by complex numbers.
Category: High Energy Particle Physics

[3] viXra:1410.0012 [pdf] submitted on 2014-10-03 16:53:32

Information Entropy and Correlations in Prime Kaluza- Klein modes

Authors: E.Koorambas
Comments: 3 Pages.

The difference between two consecutive prime Kaluza-Klein (KK) modes is defined as the distance between the primes KK modes. We study the statistical properties of the distances and their increments (the difference between two consecutive distances) for a sequence comprising the first 10^7 prime KK modes. The information entropy production for prime KK modes may open a window for extra dimensions ruled out by experiments.
Category: High Energy Particle Physics

[2] viXra:1410.0010 [pdf] submitted on 2014-10-02 15:45:02

7.1 Kev and 35 Gev Dark Matter: More Signs of Supersymmetry

Authors: Bernard Riley
Comments: 11 Pages.

A 7.1 keV dark matter fermion in partnership with a 35 GeV scalar WIMP would join the electron, the up quark and their previously hypothesised supersymmetric partners in a spectacular arrangement on the mass levels of the Supersymmetric Planck Model. All three partnerships are arranged symmetrically about the precise centre, at the scale of 16 MeV, of a symmetrical pattern of coincident mass levels that extends over 35 orders of magnitude. The implied dynamical supersymmetry-breaking scale lambda coincides with coincident mass levels at the centre of another symmetrical pattern. The investigation has revealed new evidence of quark-lepton symmetry.
Category: High Energy Particle Physics

[1] viXra:1410.0002 [pdf] submitted on 2014-10-01 08:13:45

An Intimate Relationship Between Higgs Forces, Dark Matter, and Dark Energy

Authors: Antonio A. Colella
Comments: 7 Pages.

Our universe’s eight permanent matter particles are the: up quark, down quark, electron, electron-neutrino, muon-neutrino, tau-neutrino, zino, and photino. The zino and photino are dark matter particles. Each of these eight permanent matter particles has an associated supersymmetric Higgs force. The sum of the eight Higgs force energies of these eight permanent matter particles is dark energy.
Category: High Energy Particle Physics