Interactions between Electromagnetic Fields and Matter

Principal Mathematical Symbols Used in This WorkSome Universal Constants (SI-units)Introductory Remarks 1. Storing Matter and Dissipating Matter 2. Some Phenomenological Considerations to the Reactions of MatterI. Matter as a Conglomeration of Charged Mass Points in the Electromagnetic Field 1. The Hamiltonian of Charged Particles in the External Field 2. Analysis of the Hamiltonian 2.1. Field Analysis 2.2. The Interaction Terms 3. Multi-pole Moments 3.1. Dipole, Quadrupole, Octopole Moments 3.2. Permanent and Induced Moments 3.3. Tentative Illustrative and Conceptual Interpretation of the Individual MomentsII. Microscopic Models, Characteristic Curves, Processes 1. Models of Matter 2. The Equation of Motion of Charged Particles in the Electromagnetic Field 2.1. Derivation from the Hamiltonian 2.2. Equation of Motion with Purely Electric Fields 2.3. Equation of. Motion with Purely Magnetic Fields 3. Characteristic Curves 3.1. Electric Characteristic Curves 3.2. Magnetic Characteristic Curves 3.3. The Derivatives of the Characteristic Curves, Their Frequency Dependence 3.4. Comparison with Well-known and Proven Storage Characteristics; Microscopic and Quasimacroscopic Bonds 4. Survey of the Interaction Processes 4.1. The Calculation of the Mixing 4.2. The Processes 5. Transition to the Discussion in Terms of Quantum Mechanics 5.1. Transfer, with the Help of the Correspondence Principle, of Fourier Coefficients into Matrix Elements 5.2. Conclusions from the MatricesIII. The Quantum-mechanical Treatment of the Interactions 1. The General Solution Scheme 1.1. The Expectation Values as Theoretical Predictions of Observable Quantities 1.2. Determination of the Expectation Values 2. Special Steady-state Formulations 2.1. The Perturbed Hamiltonian 2.2. Steady-state Expectation ValuesIV. Special Processes I: Static and Quasistatic (off-resonance) Interactions 1. The Static Expansion Coefficients 1.1. General Considerations Concerning the Solution of the Set of Equations of the Static Expansion Coefficients 1.2. Determination of the General Expansion Coefficients 2. The Static Characteristic Curve 2.1. The Single-field Characteristic Curve and Its Special Form in a Two-state System 2.2. Generalizations and Specializations 2.3. Some Interaction Processes 3. Considerations Concerning the Operating Point of MatterV. Special Processes II: Dynamic Processes, in Particular Resonance Processes 1. Single-field Processes 1.1. The Expansion Coefficients and Expectation Values of the Moments 1.2. Linear Processes 1.3. Nonlinear Single-field Processes 2. Multi-field Processes 2.1. Controllable Processes 2.2. Harmonic Processes 2.3. Mixing Processes 3. Power Relations of Nonlinear Resonance Processes 3.1. The Process Power Values with Resonant Frequency Doubling and Mixing 3.2. General Power Relations of Phase-insensitive Resonance Processes and Determination of Their Transition Probabilities by Way of Phase-sensitive Interactions 4. On the Presentation of the Resonance ProcessesVI. Macroscopic Structures 1. The Generalized Field Equation 2. Structures with Reactions due to the Linear Process 2.1. The Solution of the Elementary Case 2.2. The Solution with Consideration of the Tensor Properties of the Susceptibility 3. Structures with Reactions via Nonlinear Single-field Processes 3.1. The Field Equation 3.2. The Solution 3.3. Discussion of the Solution 4. Frequency Doubling in Macroscopic Structures 4.1. The Field Equations 4.2. The Solution 5. Frequency Mixing in Macroscopic Structures 5.1.