Table of contents
Mastering Maxwell's Equations
From field concepts to professional electromagnetic modeling and applications
Read each section in order. Every title can be opened as a TheoryTrace document.
- Cover1
- Copyright2
- How to read this book3
- Introduction4
- Chapter 1: The Electromagnetic Worldview5
- Chapter 2: Mathematical Tools for Fields6
- Chapter 3: Integral Theorems and Physical Meaning7
- Chapter 4: Charge, Current, and Conservation8
- Chapter 5: Electrostatics and Coulomb's Law9
- Chapter 6: Solving Electrostatic Boundary-Value Problems10
- Chapter 7: Magnetostatics and Steady Currents11
- Chapter 8: Magnetic Materials and Magnetization12
- Chapter 9: Electric Fields in Matter13
- Chapter 10: Faraday's Law and Electromagnetic Induction14
- Chapter 11: Ampere-Maxwell Law and Displacement Current15
- Chapter 12: Maxwell's Equations in Integral and Differential Form16
- Chapter 13: Boundary Conditions and Interface Physics17
- Chapter 14: Electromagnetic Energy, Momentum, and Power Flow18
- Chapter 15: Electromagnetic Waves in Vacuum19
- Chapter 16: Waves in Materials20
- Chapter 17: Reflection, Refraction, and Transmission21
- Chapter 18: Potentials, Gauge Freedom, and Retarded Solutions22
- Chapter 19: Radiation from Accelerating Charges and Antennas23
- Chapter 20: Transmission Lines and Guided Waves24
- Chapter 21: Electromagnetism and Special Relativity25
- Chapter 22: Numerical Electromagnetics and Professional Modeling26
- Chapter 23: Applications Across Physics and Engineering27
- Chapter 24: Problem-Solving Mastery with Maxwell's Equations28
- Conclusion29