High Energy Particle Physics

0703 Submissions

[6] viXra:0703.0053 [pdf] submitted on 25 Mar 2007

A Hidden Dimension, Clifford Algebra, and Centauro Events

Authors: Carl Brannen
Comments: recovered from sciprint.org

This paper eshes out the arguments given in a 20 minute talk at the Phenomenology 2005 meeting at the University of Wisconsin at Madison, Wisconsin on Monday, May 2, 2005. The argument goes as follow: A hidden dimension is useful for explaining the phase velocity of quantum waves. The hidden dimension corresponds to the proper time parameter of standard relativity. This theory has been developed into a full gravitational theory, "Euclidean Relativity" by other authors. Euclidean relativity matches the results of Einstein's gravitation theory. This article outlines a compatible theory for elementary particles. The massless Dirac equation can be generalized from an equation of matrix operators operating on vectors to an equation of matrix operators operating on matrices. This allows the Dirac equation to model four particles simultaneously. We then examine the natural quantum numbers of the gamma matrices of the Dirac equation, and generalize this result to arbitrary complexified Clifford algebras. Fitting this "spectral decomposition" to the usual elementary particles, we find that one hidden dimension is needed as was similarly needed by Euclidean relativity, and that we need a set of eight subparticles to make up the elementary fermions. These elementary particles will be called \binons", and each comes in three possible subcolors. The details of the binding force between binons will be given as a paper associated with a talk by the author at the APSNW 2005 meeting at the University of Victoria, at British Columbia, Canada on May 15, 2005. After an abbreviated introduction, this paper will concentrate on the phenomenological aspects of the binons, particularly as applied to the Centauro type cosmic rays, and gamma-ray bursts.
Category: High Energy Particle Physics

[5] viXra:0703.0051 [pdf] submitted on 25 Mar 2007

On the Large N Limit of Exceptional Jordan Matrix Models, Chern-Simons Foliations and M, F Theory

Authors: Carlos Castro
Comments: recovered from sciprint.org

The large N ...
Category: High Energy Particle Physics

[4] viXra:0703.0050 [pdf] submitted on 25 Mar 2007

Chern-Simons (Super) Gravity and E8 Yang-Mills from a Clifford Algebra Gauge Theory

Authors: Carlos Castro
Comments: recovered from sciprint.org

It is shown why the E8 Yang-Mills can be constructed from a Cl(16) algebra Gauge Theory and why the 11D Chern-Simons (Super) Gravity theory is a very small sector of a more fundamental theory based on a Cl(11) algebra Gauge theory. These results may shed some light into the origins behind the hidden E8 symmetry of 11D Supergravity and reveal more important features of a Clifford-algebraic structure underlying M, F theory.
Category: High Energy Particle Physics

[3] viXra:0703.0049 [pdf] submitted on 25 Mar 2007

Noncommutative Branes in Clifford-Space Backgrounds and Moyal-Yang Star Products with uv-ir Cutoffs

Authors: Carlos Castro
Comments: recovered from sciprint.org

A novel Moyal-Yang star product deformation of generalized p-brane actions in Clifford-space target backgrounds involving multivectors ( polyvectors, antisymmetric tensors ) valued coordinates is constructed based on the novel Moyal-Yang star product deformations of Generalized-Yang-Mills theories. ...
Category: High Energy Particle Physics

[2] viXra:0703.0048 [pdf] submitted on 25 Mar 2007

On the Coupling Constants, Geometric Probability and Shilov Boundaries

Authors: Carlos Castro
Comments: recovered from sciprint.org

By recurring to Geometric Probability methods it is shown that the coupling constants, ...
Category: High Energy Particle Physics

[1] viXra:0703.0002 [pdf] submitted on 10 Mar 2007

An Identity Crisis for the Casimir Operator

Authors: Thomas R. Love
Comments: recovered from sciprint.org

Lie groups and Lie algebras play a fundamental role in classical mechanics, electrodynamics, quantum mechanics, relativity, and elementary particle physics.
Category: High Energy Particle Physics