Main publications. Abstracts and contents of the monographs
The Problem of Electron and Superluminal Signals
(Contemporary Fundamental Physics)
by V. P. Oleinik
Nova Science Publishers, Inc., New York, June 2001, 229 pages
Abstract. The own field of electron, treated as an open self-organizing system, is a bearer of superluminal signals, which may be used for the creation of qualitatively new systems of information transfer. The course of time in some region of space depends on the character of physical processes occurring in it and thus one can control time by changing its course with the aid of material processes. These conclusions are not in conflict with the relativity theory; they follow immediately from relativistic equations of motion and are an essential development of conventional notions of space and time. At present all the necessary prerequisites are available, both theoretical and technical, for practical mastering of own fields of particles and physical properties of time.
CONTENTS
Preface
Notation
Chapter 1 Electron as an Open Self-Organizing System
Section 1-1 Physical Ideas and Main Results
Section 1-2 Model of Open System
Section 1-3 Equations for the Vortex and Potential Components of Electromagnetic Field
Section 1-4 Self-Acting Field of Electron
Section 1-5 Interaction of the Field of Electron with Vortex Electromagnetic Field
Section 1-6 Action of the System of Interacting Fields. Relativistic Equation for the Field of Electron
Section 1-7 Vortex Component of the Energy-Momentum Tensor of Electromagnetic Field
Section 1-8 Second Quantization of the Vortex Electromagnetic Field
Section 1-9 Energy-Momentum Tensor of Electrically Charged Fields
Section 1-10 Solution of the Dynamical Equation for the Charged Self-Acting Particles in Nonrelativistic Approximation
Section 1-11 Self-Action Constant
Section 1-12 Wave Function of Electron without Regard for the Vortex Current
Section 1-13 Wave Function of Electron with Allowance for the Vortex Current
Section 1-14 Hydrogen Atom. Relativistic Theory
Section 1-15 Nonrelativistic Limit of the Dynamical Equation. Positronic states
Section 1-16 Nonstationary States of Electron in External Field. The Ehrenfest Theorem
Section 1-17 Quantum Model of the Field of Electrically Charged Matter
Section 1-18 Set of Several Self-Acting Particles
Section 1-19 Stationary Perturbation Theory
Section 1-20 Temporal Perturbation Theory
Section 1-21 Second Quantization of the Field of Electrically
Charged Particles
Chapter 2 The Own Field of Electron and Superluminal Signals
Section 2-1 Two Mechanisms of Transfer of Electromagnetic Interaction - Corpuscular and Classical
Section 2-2 Vortex and Potential Components of the Own Field of Electrically Charged Particles
Section 2-3 4-Potentials and Green's Functions
Section 2-4 Calculation of Potentials and Field Strengths for the Field Created by a Point Electric Charge
Section 2-5 Oscillations of an Electrically Charged Particle
Section 2-6 Vortex Own Field Created by a Stream of Electrons
Section 2-7 Physical Mechanism of the Origin of Superluminal Signals
Section 2-8 Superluminal Signals and STR
Section 2-9 Phenomenon of Relativity of Physical Processes and Prediction of Future
Section 2-10 Local Dynamical Inhomogeneity of Time and STR
Section 2-11 Physical Effects Caused by Superluminal Signals
Conclusion Philosophical Aspects of the Theory
Appendix 1 Spherical Functions
Appendix 2 Spherical Spinors
Bibliography
Index
