Electricity and Magnetism
Contents and suggested schedule
The following list gives the content of each lesson, its corresponding
section in the book and suggested completion times (in weeks).
Table of Contents for Physics C - Electricity and Magnetism.
lesson book lectures
------ ---- --------
1010 Explaining Some Details of the Course.
1020 A Simple Experiment.
1030 18.1 The Electrical Charge.
1040 18.2 Charging by Induction.
1050 18.3 Coulomb's Law.
1060 18.3 Comparing Gravitational Interaction with
Coulomb's Law.
1070 18.4 The Electrical Field.
1080 18.4 The Electrical Field of a System of N Particles
1090 18.4 The Electrical Dipole.
1100 18.5 Field Lines.
1110 18.6 The Cathode Ray Tube.
1120 18.7 The Effect of an Electrical Field on an
Electrical Dipole.
1130 19.1 Continuous Charge Distributions.
1140 19.1 Continuous Charge Distributions-Example.
1150 19.1 The Electrical Field Generated by a Charged Ring.
1160 19.1 The Electrical Field Generated by a Charged Disk.
1170 19.2 Gauss's Law-The Electrical Flux.
1180 19.3 Gauss's Law-Follow Up.
1190 19.3 Gauss's Law-Example 1.
1200 19.3 Gauss's Law-Example 2.
1210 19.3 Gauss's Law-Example 3.
1220 19.3 Gauss's Law-Example 4.
1230 19.3 Gauss's Law-Example 5.
1240 19.4 Conductors.
1250 20.1 Electrical Potential.
1260 20.1 The eV.
1270 20.2 Potential Due to a System of Point Charges.
1280 20.2 Potential Due to a System of Point Charges.
1290 20.4 Electrical Potential for a Ring of Charges-Example.
1300 20.4 Electrical Potential for a Disk of Charges-Example.
1310 20.4 Electrical Potential for a Spherical Shell
of Charges-Example.
1320 20.5 Electrical Field and Potential-Example.
1330 20.5 Electrical Field and Potential: The Gradient.
1340 20.5 Electrical Field and Potential: The Gradient-Example.
1350 20.5 Electrical Field and Potential: The Gradient-Example.
1355 20.5 Gauss' Law Drill.
1360 20.6 Equipotential Surfaces.
1370 21.1 Capacitors and Dielectrics.
1380 21.2 The Cylindrical Capacitor.
1390 21.3 Dielectrics.
1400 21.4 Stored Energy.
1410 21.5 Combinations of Capacitors.
1420 22.1 Electrical Current.
1430 22.1 Electrical Current-Example.
1440 22.2 Ohm's Law.
1450 22.2 Resistance and Temperature Coefficients.
1460 22.3 Batteries.
1470 22.4 Combinations of Resistors.
1480 22.5 A Simple Model for the Theory of Conductors.
1490 23.1 Kirchoff's Rules.
1500 23.2 RC Circuits
1510 23.2 RC Circuits-Charging the Capacitor.
1520 24.1 The Magnetic Field.
1530 24.1 Units of the Magnetic Field.
1540 24.2 Motion of a Single Charge in a Magnetic Field.
1550 24.2 Thomson's Experiment.
1560 24.3 Torques on Loops.
1570 25.1 Sources of the Magnetic Field.
1580 25.2 Conservation of Magnetic Field.
1590 25.2 Forces Between Two Protons.
1600 25.2 Magnetic Field Due to an Electrical Current.
1610 25.2 Magnetic Field Produced by a Solenoid.
1620 25.2 Magnetic Field Produced by a Long Straight Wire.
1630 25.2 Magnetic Field Between Two Wires.
1640 25.4 The Magnetic Equivalent to Gauss' Law.
1650 25.4 Ampere's Law-Examples.
1655 25.4 Ampere's Law Drill.
1660 26.1 Magnetic Induction.
1670 26.2 EMF and Faraday's Law.
1680 26.3 Lenz's Law.
1690 26.3 Lenz's Law-Examples.
1700 26.4 Motional EMF.
1705 26.4 EMF and Induction Drill.
1708 26.6 Automobile's Electrical System.
1710 26.7 Inductance.
1720 26.7 Mutual Inductance.
1730 26.8 LR Circuits.
1740 29.2 Maxwell's Equations.
1750 29.2 Maxwell's Equations-Follow Up.
1760 29.2 The Differential Form of Maxwell's Equations.
1770 28.1 AC Circuits.
1780 28.1 RMS Values.
1790 28.2 AC Circuits with Inductors.
1800 28.2 AC Circuits with Inductors and Capacitors.
1810 28.4 RLC Circuits.
1820 28.5 RLC Circuits with a Generator.
1830 Electromagnetism Final Exam.
1840 Conclusion.