High Energy Particle Physics

1211 Submissions

[6] viXra:1211.0164 [pdf] submitted on 2012-11-29 10:44:29

Color and Isospin Waves from Tetrahedral Shubnikov Groups

Authors: Bodo Lampe
Comments: 8 Pages.

This note supplements a recent article \cite{lamm} in which it was pointed out that the observed spectrum of quarks and leptons can arise as quasi-particle excitations in a discrete internal space. The paper concentrated on internal vibrational modes and it was only noted in the end that internal spin waves ('mignons') might do the same job. Here it will be shown how the mignon-mechanism works in detail. In particular the Shubnikov group $A_4 + S ( S_4 - A_4)$ will be used to describe the spectrum, and the mignetic ground state is explicitly given.
Category: High Energy Particle Physics

[5] viXra:1211.0151 [pdf] replaced on 2012-12-14 10:20:46

Why Baryons Are Yang-Mills Magnetic Monopoles

Authors: Jay R. Yablon
Comments: 69 Pages. This is the final version of the paper that will be published in January 2013 in Number 4, Volume 35, 2012 pp 401-468 of the Hadronic Journal

We demonstrate that Yang-Mills Magnetic Monopoles naturally confine their gauge fields, naturally contain three colored fermions in a color singlet, and that mesons also in color singlets are the only particles they are allowed to emit or absorb. SU(3)C QCD as it has been extensively studied and confirmed is understood in broader context, with no contradiction, to be a consequence of baryons being Yang-Mills magnetic monopoles. Protons and neutrons are naturally represented in the fundamental representation of this group. We use the t’Hooft monopole Lagrangian with a Gaussian ansatz for fermion wavefunctions to demonstrate that these monopoles can be made to interact only at very short range as is required for nuclear interactions, and we establish topological stability following symmetry breaking from an SU(4) group using the B-L (baryon minus lepton number) generator. Finally, the mass of the electron is accurately predicted based on the masses of the up and down quarks to about 3% from the experimental mean for the quark masses, and confinement of quarks occurs energetically via fantastically strong negative binding energies that accord very well with experimental nuclear data. All of this makes Yang-Mills magnetic monopoles worthy of serious consideration and further development as baryons.
Category: High Energy Particle Physics

[4] viXra:1211.0137 [pdf] submitted on 2012-11-23 08:49:53

Spinors to World-Line Strings to Kerr-Newman Fermions to Schwinger Sources to Wyler/Hua Geometry

Authors: Frank Dodd Tony Smith Jr
Comments: 5 Pages.

E8 Physics emerges from fundamental spinor fermions to condense into a 26-dim String structure with strings as fermion World-Lines with each fundamental fermion being surrounded by a Quantum Cloud that has Kerr-Newman physical structure corresponding to a Schwinger Source region with complex harmonic Wyler/Hua Green's function propagator. The Wyler/Hua complex bounded domain structure allows realistic calculation of force strength constants and particle masses. This outline sketch omits many details which are covered in vixra 1108.0027
Category: High Energy Particle Physics

[3] viXra:1211.0133 [pdf] submitted on 2012-11-22 12:14:14

The Observed Higgs Boson as the Avatar Higgs Boson

Authors: Ding-Yu Chung
Comments: 34 Pages.

The observed Higgs boson at the LHC (Large Hadron Collider) is the Avatar Higgs boson as the dual SM (Standard Model) Higgs boson-forbidden lepton condensate. The SM Higgs boson is filled with the forbidden lepton condensate to become the Avatar Higgs boson. The forbidden lepton is outside of the SM three lepton families, so the single forbidden lepton cannot exist alone, and the forbidden lepton can exist only in the forbidden lepton condensate as the composite of forbidden lepton-antilepton. Unable to decay into the SM leptons and quarks, the forbidden lepton condensate decays into diphoton to account for the observed excess diphoton deviated from the Standard Model. Other decay modes of the Avatar Higgs boson follow the decay modes of the SM Higgs boson as observed. The calculated mass of the forbidden lepton condensate is 128.8 GeV in good agreements with the observed 125 or 126 GeV. The Higgs boson is the Goldstone boson in the Standard Model for the electroweak interaction. The transformation (spontaneous symmetry breaking) between massive particle and massless particle is through the massless scalar Goldstone boson. The addition of the Goldstone boson to a massless particle results in a massive particle. Near the beginning of our universe, the addition of the Goldstone boson converted some massless particles to massive particles to differentiate different forces and particles. During this process for the symmetry breaking in the electroweak force, the remnant of the Higgs boson acquired the mass of the forbidden lepton condensate to become the Avatar Higgs boson. In this paper, the space-object structures, cosmology, and the periodic table of elementary particles are described.
Category: High Energy Particle Physics

[2] viXra:1211.0125 [pdf] submitted on 2012-11-21 08:32:25

A Relativistic QFT Basis for Spin-0 Boson Mass Differences in CMS and Atlas

Authors: Nige Cook
Comments: 2 Pages.

CERN’s Large Hadron Collider detected a possible difference in masses between the CMS detector channels for electromagnetic decay (h→γγ) and ATLAS’s weak boson decay chain detector (h→ZZ→4l); ATLAS gave 123.5 GeV for weak decay chain h→ZZ→4l, while CMS gave 126.5 GeV for h→γγ. We argue that if this mass difference is real (rather than a systematic detector miscalibration of some kind), it indicates a statistical relativistic effect: the Lorentz contraction in the direction of motion affects self-interactions of a moving spin-0 massless boson with its own field quanta, affecting weak and electromagnetic decays to a differing extent. So in a spectrum of massive spin-0 boson velocities produced by an LHC collision, the fastest moving massive spin-0 bosons could be more likely than expected to decay by double gamma emission; the slower ones might be expected to be more likely than expected to undergo weak decays and four lepton emissions. The higher the speed, the greater the slowing due to time-dilation on massive Z boson decay processes, whereas there is no time-dilation velocity effect for massless gammas (which go at light velocity in regardless).
Category: High Energy Particle Physics

[1] viXra:1211.0049 [pdf] submitted on 2012-11-09 19:55:17

Underlying Symmetry Among the Quark and Lepton Mixing Angles (Five Year Update)

Authors: J. S. Markovitch
Comments: 9 Pages.

In 2007 a mathematical model encompassing both quark and lepton mixing was introduced. As five years have elapsed since its introduction it is timely to assess the model's accuracy. Despite large conflicts with experiment at the time of its introduction, five of six predicted angles now fit experiment fairly closely. The one angle incorrectly forecast necessitates a small change to the model's original framework (essentially, a sign is toggled). This change retains most of the model's original economy, while being interesting in its own right. The model's predicted mixing angles in degrees are 45, 33.210911, and 8.034394 (new) for leptons; and 12.920966, 2.367442, and 0.190986 for quarks.
Category: High Energy Particle Physics