High Energy Particle Physics

1002 Submissions

[3] viXra:1002.0054 [pdf] submitted on 24 Feb 2010

A Preon Model from Manasson's Theory

Authors: Fabrizio Vassallo
Comments: 9 pages.

V. Manasson has applied dissipative chaos theory to particle physics, deriving a simple relation between the fine structure constant and Feigenbaum delta constant. It is presented a preon model based on Manasson's theory. The model is intended as a naive toy one, as it makes use of unjustified assumptions, as e.g. the possibility of the existence of neither fermionic nor bosonic particles in 3+1 spacetime.
Category: High Energy Particle Physics

[2] viXra:1002.0052 [pdf] submitted on 24 Feb 2010

Solving the Fermion Flavor Problem using Renormalization Group Flow

Authors: Ervin Goldfain
Comments: 12 pages. This is a sequel to a paper published in Communications in Nonlinear Science and Numerical Simulation 13 (2008) 1845-1850.

A long-standing puzzle of the current Standard Model for particle physics is that both leptons and quarks arise in replicated patterns. Our work suggests that the number of fermion flavors may be directly derived from the dynamics of Renormalization Group (RG) equations. Specifically, we argue that the number of flavors results from demanding stability of the RG flow about its fixed-point solution.
Category: High Energy Particle Physics

[1] viXra:1002.0032 [pdf] submitted on 17 Feb 2010

A Scalar-Energy Field That Predicts the Mass of The Electron-Neutrino

Authors: Michael Harney
Comments: 5 pages.

Using Wolff's model of spherical-wave centers, a scalar energy field is derived between rest-energy of a particle and potential energy of a hypothetical space fabric. The simple formula of mc2 = .5kx2 that results reveals a different elasticity constant k for each particle, and based on the knowledge of electro-weak unification which requires the constants k for the electron and neutrino to be the same, a mass for the electron-neutrino is predicted to be 0.065 eV.
Category: High Energy Particle Physics