Tabla de Contenidos:
  • 1. Review of Maxwell Equations and Units
  • Maxwell Equations in MKS System of Units
  • Major and Minor Magnetic Hysteresis Loops
  • Tensor and Dyadic Quantities
  • Maxwell Equations in Gaussian System of Units
  • External, Surface, and Internal Electromagnetic Fields
  • Problems
  • Appendix 1.A. Conversion of Units
  • References
  • Solutions
  • 2. Classical Principles of Magnetism
  • Historical Background
  • First Observation of Magnetic Resonance
  • Definition of Magnetic Dipole Moment
  • Magnetostatics of Magnetized Bodies
  • Electrostatics of Electric Dipole Moment
  • Relationship between B and H Fields
  • General Definition of Magnetic Moment
  • Classical Motion of the Magnetic Moment
  • Problems
  • Appendix 2.A
  • References
  • Solutions
  • 3. Introduction to Magnetism
  • Energy Levels and Wave Functions of Atoms
  • Spin Motion
  • Intra-Exchange Interactions
  • Heisenberg Representation of Exchange Coupling
  • Multiplet States
  • Hund Rules
  • Spin-Orbit Interaction
  • Lande gj-Factor
  • Effects of Magnetic Field on a Free Atom
  • Crystal Field Effects on Magnetic Ions
  • Superexchange Coupling between Magnetic Ions
  • Double Superexchange Coupling
  • Ferromagnetism in Magnetic Metals
  • Problems
  • Appendix 3.A. Matrix Representation of Quantum Mechanics
  • References
  • Solutions
  • 4. Free Magnetic Energy
  • Thermodynamics of Noninteracting Spins: Paramagnets
  • Ferromagnetic Interaction in Solids
  • Ferrimagnetic Ordering
  • Spinwave Energy
  • Effects of Thermal Spinwave Excitations
  • Free Magnetic Energy
  • Single Ion Model for Magnetic Anisotropy
  • Pair Model
  • Demagnetizing Field Contribution to Free Energy
  • Numerical Examples
  • Cubic Magnetic Anisotropy Energy
  • Uniaxial Magnetic Anisotropy Energy
  • Problems
  • References
  • Solutions
  • 5. Phenomenological Theory
  • Smit and Beljers Formulation
  • Examples of Ferromagnetic Resonance
  • Simple Model for Hysteresis
  • General Formulation
  • Connection between Free Energy and Internal Fields
  • Static Field Equations
  • Dynamic Equations of Motion
  • Microwave Permeability
  • Normal Modes
  • Magnetic Relaxation
  • Free Energy of Multi-Domains
  • Problems
  • References
  • Solutions
  • 6. Electrical Properties of Magneto-Dielectric Films
  • Basic Difference between Electric and Magnetic Dipole Moments
  • Electric Dipole Orientation in a Field
  • Equation of Motion of Electrical Dipole Moment in a Solid
  • Free Energy of Electrical Materials
  • Magneto-Elastic Coupling
  • Microwave Properties of Perfect Conductors
  • Principles of Superconductivity: Type I
  • Magnetic Susceptibility of Superconductors: Type I
  • London's Penetration Depth
  • Type-II Superconductors
  • Microwave Surface Impedance
  • Conduction through a Non-Superconducting Constriction
  • Isotopic Spin Representation of Feynman Equations
  • Problems
  • Appendix 6.A
  • References
  • Solutions
  • 7. Kramers-Kronig Equations
  • Problems
  • References
  • Solutions
  • 8. Electromagnetic Wave Propagation in Anisotropic Magneto-Dielectric Media
  • Spinwave Dispersions for Semi-Infinite Medium
  • Spinwave Dispersion at High k-Values
  • The k = 0 Spinwave Limit
  • Sphere
  • Thin Films
  • Needle
  • Surface or Localized Spinwave Excitations
  • Pure Electromagnetic Modes of Propagation: Semi-Infinite Medium
  • Coupling of the Equation of Motion and Maxwell's Equations
  • Normal Modes of Spinwave Excitations
  • Magnetostatic Wave Excitations
  • M Perpendicular to Film Plane
  • H in the Film Plane
  • Ferrite Bounded by Parallel Plates
  • Problems
  • Appendix 8.A
  • Perpendicular Case
  • In Plane Case
  • References
  • Solutions
  • 9. Spin Surface Boundary Conditions
  • A Quantitative Estimate of Magnetic Surface Energy
  • Another Source of Surface Magnetic Energy
  • Static Field Boundary Conditions
  • Dynamic Field Boundary Conditions
  • Applications of Boundary Conditions
  • H T to the Film Plane
  • H // to the Film Plane
  • Electromagnetic Spin Boundary Conditions
  • Problems
  • Appendix 9.A
  • Perpendicular Case
  • In Plane Case
  • References
  • Solutions
  • 10. Matrix Representation of Wave Propagation
  • Matrix Representation of Wave Propagation in Single Layers
  • (//) Case
  • (T) Case
  • The Incident Field
  • Ferromagnetic Resonance in Composite Structures: No Exchange Coupling
  • Ferromagnetic Resonance in Composite Structures: Exchange Coupling
  • (T) Case
  • Boundary Conditions
  • (//) Case
  • Boundary Conditions (// FMR)
  • Problems
  • Appendix 10.A
  • Calculation of Transmission Line Parameters from [A] Matrix
  • Microwave Response to Microwave Cavity Loaded with Magnetic Thin Film
  • References
  • Solutions.