| Preface | |
| Review of Maxwell Equations and Units | p. 1 |
| Maxwell's Equations in MKS System of Units | p. 1 |
| Maxwell's Equations in CGS System of Units | p. 4 |
| External, Surface and Internal Electromagnetic Fields | p. 6 |
| Classical Principles of Magnetism | p. 12 |
| Historical Background | p. 12 |
| First Observation of Magnetic Resonance | p. 12 |
| Definition of Magnetic Dipole Moment | p. 13 |
| Magnetostatics of Magnetized Bodies | p. 19 |
| General Definition of Magnetic Moment | p. 24 |
| Introduction to Magnetism | p. 31 |
| Magnetism at the Atomic Scale | p. 31 |
| Spin Motion | p. 35 |
| Matrix Representation of Quantum Mechanics | p. 38 |
| Effects of Magnetic Field to a Free Atom | p. 41 |
| Spin-Orbit Interaction | p. 46 |
| Exchange Interaction | p. 47 |
| Hund's Rule | p. 52 |
| Lande's g[actual symbol not reproducible]-Factor | p. 56 |
| Free Magnetic Energy | p. 62 |
| Thermodynamics of Non Interacting Spins - Paramagnets | p. 62 |
| Exchange Interaction in Solids - Ferromagnets | p. 63 |
| Ferrimagnetic Ordering | p. 67 |
| Spinwave Energy | p. 69 |
| Dipole-Dipole Interaction | p. 72 |
| Single Ion Model For Uniaxial Magnetic Anisotropy | p. 76 |
| Free Magnetic Energy | p. 79 |
| Numerical Examples | p. 81 |
| Garnet Material | p. 82 |
| Phenomenological Theory | p. 87 |
| Smit and Beljers Formulation | p. 87 |
| Examples of Ferromagnetic Resonance | p. 89 |
| General Formulation | p. 102 |
| Connection Between the Free Energy and the Internal Fields | p. 103 |
| Static Field Equations | p. 105 |
| Dynamic Equations of Motion | p. 106 |
| Microwave Permeability | p. 107 |
| Normal Modes | p. 109 |
| Magnetic Relaxation | p. 113 |
| Free Energy of Multidomains | p. 117 |
| Electrical Properties of Magnetic Films | p. 125 |
| Basic Difference Between Electric and Dipole Moments | p. 125 |
| Electric Dipole Orientation in a Field | p. 126 |
| Equation of Motion of Electrical Dipole Moment in a Solid | p. 127 |
| Free Energy of Electrical Materials | p. 130 |
| Microwave Properties of Perfect Conductors | p. 132 |
| Principles of Superconductivity - Type I | p. 134 |
| Magnetic Susceptibility of Superconductors | p. 141 |
| London's Penetration Depth | p. 142 |
| Microwave Surface Impedance | p. 145 |
| Type-II Superconductors | p. 147 |
| Conduction Through a Non-Superconducting Constriction | p. 149 |
| Isotropic Spin Representation of Feynman Equations | p. 152 |
| Kramers-Kronig Relations | p. 163 |
| Electromagnetic Wave Propagation in Magnetic Films | p. 171 |
| Magnetostatic Regime | p. 177 |
| Electromagnetic Wave Propagation in Films | p. 184 |
| Ferrite Bounded by Parallel Plates | p. 187 |
| Power Transmission - TE Mode | p. 189 |
| Propagation Loss | p. 190 |
| Dielectric Loss | p. 190 |
| Ferrite Film in a Microwave Cavity | p. 192 |
| Magnetic Surface Boundary Condition | p. 201 |
| A Quantitative Estimate of Magnetic Surface Energy | p. 203 |
| Another Source of Surface Magnetic Energy | p. 205 |
| Static Field Boundary Conditions | p. 207 |
| Dynamic Field Boundary Conditions | p. 208 |
| Matrix Representation of Wave Propagation in Magnetic Films | p. 217 |
| Ferromagnetic Resonance in Layered Structures - No Exchange Coupling | p. 217 |
| Transfer-Function Matrix of Periodic Layered Structures | p. 222 |
| Connection to Surface Impedance | p. 223 |
| Ferromagnetic Resonance in Layered Structures - Exchange Coupling | p. 225 |
| Spin Boundary Conditions | p. 228 |
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