Lecture Outline:
22. ELECTRIC CHARGE
22.1. Electromagnetism
22.2. Electric Charge
22.3. Conductors and Insulators
22.4. Coulomb’s Law
22.5. Charge is Quantized
22.6. Charge is Conserved
23. ELECTRIC FIELDS
23.1. Charges and Forces: A Closer
Look
23.2. The Electric Field
23.3. Electric Field Lines
23.4. The Electric Field Due to a
Point Charge
23.5. The Electric Field Due to an
Electric Dipole
23.6. The Electric Field Due to a Line
of Charge
23.7. The Electric Field Due to a
Charged Disk
23.8. A Point Charge in an Electric
Field
23.9. A Dipole in an Electric Field
24. GAUSS’ LAW
24.1. A New Look at Coulomb’s Law
24.2. Flux
24.3. Flux of an Electric Field
24.4. Gauss’ Law
24.5. Gauss’ Law and Coulomb’s Law
24.6. A Charged Isolated Conductor
24.7. Applying Gauss’ Law: Cylindrical
Symmetry
24.8. Applying Gauss’ Law: Planner
Symmetry
24.9. Applying Gauss’ Law: Spherical
Symmetry
25. ELECTRIC POTENTIAL
25.1. Electric Potential Energy
25.2. Electric Potential
25.3. Equipotential Surfaces
25.4. Calculating the Potential From
the Field
25.5. Potential Due to a Point Source
25.6. Potential Due to a Group of
Point Charges
25.7. Potential Due to an Electric
Dipole
25.8. Potential Due to a Continuous
Charge Distribution
25.9. Calculating The Field from the
Potential
25.10. Electric Potential Energy of a System of Point
Charges
25.11. Potential of a Charged Isolated Conductor
26. CAPACITANCE
26.1. The Uses of Capacitors
26.2. Capacitance
26.3. Calculating the Capacitance
26.4. Capacitors in Parallel and in
Series
26.5. Storing Energy in an Electric
Field
26.6. Capacitor with a Dielectric
26.7. Dielectric: An Atomic View
26.8. Dielectric and Gauss’ Law
27. CURRENT AND RESISTANCE
27.1. Moving Charges and Electric
Currents
27.2. Electric Current
27.3. Current Density
27.4. Resistance and Resistivity
27.5. Ohm’s Law
27.6. A Microscopic View of Ohm’s Law
27.7. Power In Electric Circuits
27.8. Semiconductors
27.9. Superconductors
28. CIRCUITS
28.1. “Pumpin” Charges
28.2. Work, Energy and Emf
28.3. Calculating The Current in a
Single-Loop Circuit
28.4. Other Single-Loop Circuits
28.5. Potential Differences
28.6. Multiloop Circuits
28.7. The Ammeter and the Voltmeter
28.8. RC Circuits
29. MAGNETIC FIELDS
29.1. The Magnetic Field
29.2. The Definition of B
29.3. Crossed Fields: Discovery of the
Electron
29.4. Crossed Fields: The Hall Effect
29.5. A Circulating Charged Particle
29.6. Cyclotrons and Synchrotrons
29.7. Magnetic Force on a
Current-Carrying Wire
29.8. Torque On a Current Loop
29.9. The Magnetic Dipole
30. MAGNETIC FIELDS DUE TO CURRENTS
30.1. Calculating The Magnetic Field
Due to a Current
30.2. Two Parallel Currents
30.3. Ampere’s Law
30.4. Solenoids and Torroids
30.5. A Current-Carrying Coil As a
Magnetic Dipole
31. INDUCTION AND INDUCTANCE
31.1. Two Symmetric Situations
31.2. Two Experiments
31.3. Faraday’s of Induction
31.4. Lenz’s Law
31.5. Induction and Energy Transfers
31.6. Induced Electric Fields
31.7. Inductors and Inductance
31.8. Self-Induction
31.9. RL Circuits
31.10. Energy Stored in a Magnetic Field
31.11. Energy Density of a Magnetic Field
31.12. Mutual Induction
33.
ELECTROMAGNETIC OSCILLATIONS AND ALTERNATING CURRENT
33.1. New
Physics-Old Mathematics
33.2. LC Oscillations,
Qualitatively
33.3. The
Electrical-Mechanical Analogy
33.4.
LC Oscillations, Quantitatively
33.5.
Damped Oscillations in a RLC Circuit
33.6.
Alternating Current
33.7.
Forced Oscillations
33.8.
Three Simple Circuits
33.9.
The Series RLC Circuit
33.10. Power
in Alternating-Current Circuits
33.11.
Transformers