UsefulLinks
Physics
Foundational Physics
Electromagnetism
1. Fundamental Concepts and Mathematical Preliminaries
2. Electrostatics
3. Electric Fields in Matter
4. Magnetostatics
5. Magnetic Fields in Matter
6. Electrodynamics
7. Conservation Laws and Energy Flow
8. Electromagnetic Waves
9. Advanced Topics
6.
Electrodynamics
6.1.
Electromagnetic Induction
6.1.1.
Faraday's Law of Induction
6.1.1.1.
Magnetic Flux
6.1.1.2.
Flux Linkage
6.1.1.3.
Induced EMF
6.1.1.4.
Integral Form
6.1.1.5.
Differential Form
6.1.2.
Lenz's Law
6.1.2.1.
Direction of Induced Current
6.1.2.2.
Energy Conservation
6.1.3.
Motional EMF
6.1.3.1.
Moving Conductors in Magnetic Fields
6.1.3.2.
Sliding Rod on Rails
6.1.3.3.
Rotating Loops
6.1.4.
Induced Electric Fields
6.1.4.1.
Non-conservative Electric Fields
6.1.4.2.
Relationship to Changing Magnetic Fields
6.2.
Inductance
6.2.1.
Self-Inductance
6.2.1.1.
Calculation Methods
6.2.1.2.
Examples
6.2.1.2.1.
Solenoid
6.2.1.2.2.
Toroidal Coil
6.2.1.2.3.
Parallel Wires
6.2.2.
Mutual Inductance
6.2.2.1.
Reciprocity Theorem
6.2.2.2.
Calculation Methods
6.2.2.3.
Transformer Principle
6.2.3.
Energy in Magnetic Fields
6.2.3.1.
Energy Stored in Inductors
6.2.3.2.
Magnetic Energy Density
6.2.3.3.
Total Magnetic Energy
6.3.
Displacement Current
6.3.1.
Inconsistency in Ampere's Law
6.3.2.
Maxwell's Correction
6.3.3.
Displacement Current Density
6.3.4.
Physical Interpretation
6.4.
Maxwell's Equations
6.4.1.
Complete Set of Equations
6.4.1.1.
Gauss's Law for Electric Field
6.4.1.2.
Gauss's Law for Magnetic Field
6.4.1.3.
Faraday's Law
6.4.1.4.
Ampere-Maxwell Law
6.4.2.
Integral Form
6.4.3.
Differential Form
6.4.4.
Maxwell's Equations in Vacuum
6.4.5.
Maxwell's Equations in Matter
6.4.6.
Boundary Conditions
6.4.7.
Gauge Invariance
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7. Conservation Laws and Energy Flow