Symmetry Breaking by Electric Discharges in Water and Formation of Lochak’s Light Magnetic Monopoles in an Extended Standard Model

Abstract

Abstract By Lochak (theory) and Urutskoiev (experiment) it has been suggested that during discharges in water (fluids) light leptonic magnetic monopoles can be created in order to explain accidents in power plants. According to Lochak these monopoles should be identified with excited neutrinos which enforces the assumption that they cannot be pointlike but must be relativistic composite particles. The structure of relativistic composite particles and their interactions can be described by a relativistically invariant nonlinear spinor field theory with local interaction, canonical quantization, self-regularization and probability interpretation. which is based on a central decomposition theorem for nonlinear differential equations The spinor field model allows to perform non-perturbative calculations and its mathematical treatment is in accordance with the basic ideas of nonperturbative algebraic representation theory of quantum fields. In this approach the Standard Model is considered to be an effective theory derived by applying weak mapping theorems which offers the chance to study processes beyond the conventional theory by an extension of the Standard Model If this model is used to describe processes during electric discharges in water with supersonic currents this leads to algebraic representations for broken CP-symmetry and necessitates to introduce a second class of vector bosons, namely the magnetic electroweak vector bosons in addition to the conventional electric electroweak vector bosons. For composite leptons and quarks coupled to this enlarged set of boson states one gets an extended Standard Model where the existence of magnetic excited neutrinos can be demonstrated. By detailed calculations the formalism is illustrated in chapters 1,2,3, while the monopoles are discussed in chapter 4.