Magnetics, dielectrics, and wave propagation with MATLAB codes - Info and Reading Options

"Magnetics, dielectrics, and wave propagation with MATLAB codes" Table Of Contents:

• 1- 1. Review of Maxwell Equations and Units
• 2- Maxwell Equations in MKS System of Units
• 3- Major and Minor Magnetic Hysteresis Loops
• 4- Tensor and Dyadic Quantities
• 5- Maxwell Equations in Gaussian System of Units
• 6- External, Surface, and Internal Electromagnetic Fields
• 7- Problems
• 8- Appendix 1.A. Conversion of Units
• 9- References
• 10- Solutions
• 11- 2. Classical Principles of Magnetism
• 12- Historical Background
• 13- First Observation of Magnetic Resonance
• 14- Definition of Magnetic Dipole Moment
• 15- Magnetostatics of Magnetized Bodies
• 16- Electrostatics of Electric Dipole Moment
• 17- Relationship between B and H Fields
• 18- General Definition of Magnetic Moment
• 19- Classical Motion of the Magnetic Moment
• 20- Problems
• 21- Appendix 2.A
• 22- References
• 23- Solutions
• 24- 3. Introduction to Magnetism
• 25- Energy Levels and Wave Functions of Atoms
• 26- Spin Motion
• 27- Intra-Exchange Interactions
• 28- Heisenberg Representation of Exchange Coupling
• 29- Multiplet States
• 30- Hund Rules
• 31- Spin-Orbit Interaction
• 32- Lande gj-Factor
• 33- Effects of Magnetic Field on a Free Atom
• 34- Crystal Field Effects on Magnetic Ions
• 35- Superexchange Coupling between Magnetic Ions
• 36- Double Superexchange Coupling
• 37- Ferromagnetism in Magnetic Metals
• 38- Problems
• 39- Appendix 3.A. Matrix Representation of Quantum Mechanics
• 40- References
• 41- Solutions
• 42- 4. Free Magnetic Energy
• 43- Thermodynamics of Noninteracting Spins: Paramagnets
• 44- Ferromagnetic Interaction in Solids
• 45- Ferrimagnetic Ordering
• 46- Spinwave Energy
• 47- Effects of Thermal Spinwave Excitations
• 48- Free Magnetic Energy
• 49- Single Ion Model for Magnetic Anisotropy
• 50- Pair Model
• 51- Demagnetizing Field Contribution to Free Energy
• 52- Numerical Examples
• 53- Cubic Magnetic Anisotropy Energy
• 54- Uniaxial Magnetic Anisotropy Energy
• 55- Problems
• 56- References
• 57- Solutions
• 58- 5. Phenomenological Theory
• 59- Smit and Beljers Formulation
• 60- Examples of Ferromagnetic Resonance
• 61- Simple Model for Hysteresis
• 62- General Formulation
• 63- Connection between Free Energy and Internal Fields
• 64- Static Field Equations
• 65- Dynamic Equations of Motion
• 66- Microwave Permeability
• 67- Normal Modes
• 68- Magnetic Relaxation
• 69- Free Energy of Multi-Domains
• 70- Problems
• 71- References
• 72- Solutions
• 73- 6. Electrical Properties of Magneto-Dielectric Films
• 74- Basic Difference between Electric and Magnetic Dipole Moments
• 75- Electric Dipole Orientation in a Field
• 76- Equation of Motion of Electrical Dipole Moment in a Solid
• 77- Free Energy of Electrical Materials
• 78- Magneto-Elastic Coupling
• 79- Microwave Properties of Perfect Conductors
• 80- Principles of Superconductivity: Type I
• 81- Magnetic Susceptibility of Superconductors: Type I
• 82- London's Penetration Depth
• 83- Type-II Superconductors
• 84- Microwave Surface Impedance
• 85- Conduction through a Non-Superconducting Constriction
• 86- Isotopic Spin Representation of Feynman Equations
• 87- Problems
• 88- Appendix 6.A
• 89- References
• 90- Solutions
• 91- 7. Kramers-Kronig Equations
• 92- Problems
• 93- References
• 94- Solutions
• 95- 8. Electromagnetic Wave Propagation in Anisotropic Magneto-Dielectric Media
• 96- Spinwave Dispersions for Semi-Infinite Medium
• 97- Spinwave Dispersion at High k-Values
• 98- The k = 0 Spinwave Limit
• 99- Sphere
• 100- Thin Films
• 101- Needle
• 102- Surface or Localized Spinwave Excitations
• 103- Pure Electromagnetic Modes of Propagation: Semi-Infinite Medium
• 104- Coupling of the Equation of Motion and Maxwell's Equations
• 105- Normal Modes of Spinwave Excitations
• 106- Magnetostatic Wave Excitations
• 107- M Perpendicular to Film Plane
• 108- H in the Film Plane
• 109- Ferrite Bounded by Parallel Plates
• 110- Problems
• 111- Appendix 8.A
• 112- Perpendicular Case
• 113- In Plane Case
• 114- References
• 115- Solutions
• 116- 9. Spin Surface Boundary Conditions
• 117- A Quantitative Estimate of Magnetic Surface Energy
• 118- Another Source of Surface Magnetic Energy
• 119- Static Field Boundary Conditions
• 120- Dynamic Field Boundary Conditions
• 121- Applications of Boundary Conditions
• 122- H T to the Film Plane
• 123- H // to the Film Plane
• 124- Electromagnetic Spin Boundary Conditions
• 125- Problems
• 126- Appendix 9.A
• 127- Perpendicular Case
• 128- In Plane Case
• 129- References
• 130- Solutions
• 131- 10. Matrix Representation of Wave Propagation
• 132- Matrix Representation of Wave Propagation in Single Layers
• 133- (//) Case
• 134- (T) Case
• 135- The Incident Field
• 136- Ferromagnetic Resonance in Composite Structures: No Exchange Coupling
• 137- Ferromagnetic Resonance in Composite Structures: Exchange Coupling
• 138- (T) Case
• 139- Boundary Conditions
• 140- (//) Case
• 141- Boundary Conditions (// FMR)
• 142- Problems
• 143- Appendix 10.A
• 144- Calculation of Transmission Line Parameters from [A] Matrix
• 145- Microwave Response to Microwave Cavity Loaded with Magnetic Thin Film
• 146- References
• 147- Solutions.

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