Covariant Electrodynamics

John M. Charap is an emeritus professor of theoretical physics at the University of London's Queen Mary College. He is the editor of Geometry of Constrained Dynamical Systems and the author of Explaining the Universe: The New Age of Physics.

Preface
1. Introduction
2. Mathematical Preliminaries
2.1. A Reminder of Vector Calculus
2.2. Special Relativity
2.3. Four-Vectors
2.4. Covariant and Contravariant Vectors
2.5. Tensors
2.6. Time Dilation and the Lorentz-FitzGerald Contraction
2.7. The Four-Velocity
2.8. Energy and Momentum
2.9. Plane Waves
2.10. Exercises for Chapter 2
3. Maxwell's Equations
3.1. Our Starting Point
3.2. The Experimental Background
3.2.1. Coulomb's Law
3.2.2. Absence of Magnetic Monopoles
3.2.3. Ørsted and Ampere
3.2.4. The Law of Biot and Savart
3.2.5. The Displacement Current
3.2.6. Faraday's Law of Induction
3.2.7. The Lorentz Force
3.3. Capacitors and Solenoids
3.3.1. Energy
3.4. Electromagnetic Waves
3.4.1. Polarization
3.4.2. Electromagnetism and Light
3.5. Exercises for Chapter 3
4. Behavior under Lorentz Transformations
4.1. The Charge-Current Density Four-Vector
4.2. The Lorentz Force
4.3. The Potential Four-Vector
4.4. Gauge Transformations
4.5. The Field-Strength Tensor
4.6. The Dual Field-Strength Tensor
4.7. Exercises for Chapter 4
5. Lagrangian and Hamiltonian
5.1. Lagrange's Equations
5.2. The Lagrangian for a Charged Particle
5.3. The Hamiltonian for a Charged Particle
5.4. The Lagrangian for the Electromagnetic Field
5.5. The Hamiltonian for the Electromagnetic Field
5.6. Noether's Theorem
5.7. Exercises for Chapter 5
6. Stress, Energy, and Momentum
6.1. The Canonical Stress Tensor
6.2. The Symmetrical Stress Tensor
6.3. The Conservation Laws with Sources
6.4. The Field as an Ensemble of Oscillators
6.5. Exercises for Chapter 6
7. Motion of a Charged Particle
7.1. Fields from an Unaccelerated Particle
7.2. Motion of a Particle in an External Field
7.2.1. Uniform Static Magnetic Field
7.2.2. Crossed E and B Fields
7.2.3. Nonuniform Static B-Field
7.2.4. Curved Magnetic Field Lines
7.3. Exercises for Chapter 7
8. Fields from Sources
8.1. Introducing the Green's Function
8.2. The Delta Function
8.3. The Green's Function
8.4. The Covariant Form for the Green's Function
8.5. Exercises for Chapter 8
9. Radiation
9.1. Potentials from a Moving Charged Particle
9.2. The Lienard-Wiechert Potentials
9.2.1. Fields from an Unaccelerated Particle
9.2.2. Fields from a Charged Oscillator
9.3. The General Case
9.4. The Multipole Expansion
9.4.1. Electric Dipole Radiation
9.4.2. Magnetic Dipole and Higher-Order Terms
9.5. Motion in a Circle
9.6. Radiation from Linear Accelerators
9.7. Radiation from an Antenna
9.8. Exercises for Chapter 9
10. Media
10.1. Dispersion
10.1.1. Newton on the "Phænomena of Colours"
10.2. Refraction
10.2.1. The Boundary Conditions at the Interface
10.3. Cerenkov Radiation
10.4. Exercises for Chapter 10
11. Scattering
11.1. Scattering from a Small Scatterer
11.2. Many Scatterers
11.3. Scattering from the Sky
11.3.1. The Born Approximation
11.3.2. Rayleigh's Explanation for the Blue Sky
11.4. Critical Opalescence
12. Dispersion
12.1. The Oscillator Model
12.1.1. The High-Frequency Limit
12.1.2. The Drude Model
12.2. Dispersion Relations
12.3. The Optical Theorem
Epilogue
Index