Syllabus

Course Meeting Times

Lectures: 4 sessions / week, 1 hour / session

Course Description

This course runs parallel to 8.02, but assumes that students have some knowledge of vector calculus. The class introduces Maxwell's equations, in both differential and integral form, along with electrostatic and magnetic vector potential, and the properties of dielectrics and magnetic materials. The class also touches on special relativity and the properties of electromagnetic waves.

Prerequisites

Physics I (8.01), Multivariable Calculus (18.02)

Textbooks

Main Text

Buy at Amazon Griffiths, David J. Introduction to Electrodynamics. 3rd ed. Upper Saddle River, NJ: Prentice Hall, 1998. ISBN: 9780138053260.

Reference Texts

Buy at Amazon Purcell, Edward M. "Electricity and Magnetism." In Berkeley Physics Course. 2nd ed. Vol. 2. New York, NY: McGraw-Hill, 1984. ISBN: 9780070049086.

Buy at Amazon Feynman, Richard P., Robert B. Leighton, and Matthew Sands. The Feynman Lectures on Physics. 2nd ed. Vol. 2. Reading, MA: Addison-Wesley, 2005. ISBN: 9780805390452.

Grading Policy

ACTIVITIES PERCENTAGES
Problem sets 25%
Exam 1 15%
Exam 2 15%
Exam 3 15%
Final exam 25%
Class participation 5%

Calendar

WEEK # SES # TOPICS KEY DATES

Week 1

Introduction, electric field

 1 Intro: Electrostatics
2 Electrostatics problem solving

Week 2

Mathematical background

 3 Vector review
4 Divergence, gradient, curl
5 Integral calculus, Dirac delta function
6 Dirac delta function, curvilinear coordinates

Week 3

Gauss's law and electric potential

 7 More curvilinear coordinates: Div and grad in spherical coordinates; Gauss's law
8 Applications of Gauss's law: Field lines, point charge, Gaussian surfaces Problem set 1 due
9 Applications of Gauss's law: Line charge, plane charge
10 Electric potential; Poisson's equation; Laplace's equation

Week 4

Work and energy in electrostatics; conductors and capacitors

 11 Electrostatic boundary conditions; conductors
12 Capacitors, dielectrics, work Problem set 2 due
13 Capacitors, work, first and second uniqueness theorems

Week 5

The method of images and multipole expansion

 14 Method of images
15 Parallel plate capacitor, electric dipole Problem set 3 due
16 Separation of variables

Week 6

Exam 1

 17 Review for exam 1
18 Exam 1

Week 7

Magnetostatics and special relativity

 19 Dielectrics
20 Magnetostatics, electric currents
21 Special relativity Problem set 4 due
22 Special relativity (cont.)

Week 8

Magnetic fields

 23 Electric fields and force
24 Magnetic fields; Lorenz force law
25 Cycloidal motion; Biot-Savart law Problem set 5 due
26 Biot-Savart law (cont.); Ampere's law Problem set 6 due

Week 9

Magnetic fields; Maxwell's laws; magnetic properties of materials

 27 Maxwell's equations
28 Induction
29 Magnetic boundary conditions; magnetic dipole
30 Magnetization; magnetic properties of materials

Week 10

Exam 2; magnetized materials

 31 Review for exam 2
32 Exam 2
33 Ampere's law in magnetized materials
34 Bound current; ferromagnetism

Week 11

Circuits

 35 Circuits
36 Circuits; undriven RC circuits; Thevenin's theorem
37 Thevenin's theorem (cont.); Ohm's law; Faraday's law; Lenz's law Problem set 7 due
38 Alternating current circuits

Week 12

Circuits (cont.)

 39 Inductance
40 Undriven RLC circuits
41 Driven RLC circuits; Ladder impedance Problem set 8 due

Week 13

Maxwell; momentum

 42 Maxwell's equations
43 Poynting vector; Maxwell stress tensor
44 Conservation of momentum; Minkowski force
45 Review for exam 3

Week 14

Electromagnetic waves

 46 Exam 3
47 Electromagnetic waves
48 Electromagnetic waves (cont.)
49 Topics for next week; relativity

Week 15

Advanced topics in relativity; quantum

 50 Faraday tensor; Maxwell; General relativity
51 Quantum Problem set 9 due
52 Schrodinger equation