Title | Lecture Notes Physics II Electricity and Magnetism Physics MIT Open Course Ware |
---|---|
Author | Jesper Petersen |
Course | Elektrokemi |
Institution | Danmarks Tekniske Universitet |
Pages | 2 |
File Size | 182.9 KB |
File Type | |
Total Downloads | 100 |
Total Views | 132 |
Elektrofysik...
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Home » Courses » Physics » Physics II: Electricity and Magnetism » Lecture Notes
Lecture Notes The lecture notes were prepared in LaTeX by James Silva, an MIT student, based upon handwritten notes.
COURSE HOME
SYLLABUS
WEEK #
SES #
TOPICS
Week 1
1
Intro: Electrostatics (PDF)
2
Electrostatics problem solving (PDF)
3
Vector review (PDF)
4
Divergence, gradient, curl (PDF)
5
Integral calculus, Dirac delta function (PDF)
6
Dirac delta function, curvilinear coordinates (PDF)
7
More curvilinear coordinates: Div and grad in spherical coordinates; Gauss's law (PDF)
8
Applications of Gauss's law: Field lines, point charge, Gaussian surfaces (PDF)
9
Applications of Gauss's law: Line charge, plane charge (PDF)
10
Electric potential; Poisson's equation; Laplace's equation (PDF)
11
Electrostatic boundary conditions; conductors (PDF)
12
Capacitors, dielectrics, work (PDF)
13
Capacitors, work, first and second uniqueness theorems (PDF)
14
Method of images (PDF)
15
Parallel plate capacitor, electric dipole (PDF)
16
Separation of variables (PDF)
17
Review for exam 1
18
Exam 1
19
Dielectrics (PDF)
20
Magnetostatics, electric currents (PDF)
21
Special relativity (PDF)
22
Special relativity (cont.) (PDF)
23
Electric fields and force (PDF)
24
Magnetic fields; Lorenz force law (PDF)
25
Cycloidal motion; Biot-Savart law (PDF)
26
Biot-Savart law (cont.); Ampere's law (PDF)
27
Maxwell's equations (PDF)
28
Induction (PDF)
29
Magnetic boundary conditions; magnetic dipole (PDF)
30
Magnetization; magnetic properties of materials (PDF)
31
Review for exam 2 (PDF)
Introduction, electric field
READINGS Week 2
LECTURE NOTES Mathematical background
ASSIGNMENTS
EXAMS Week 3
DOWNLOAD COURSE MATERIALS
Gauss's law and electric potential
Week 4 Work and energy in electrostatics; conductors and capacitors
Week 5 The method of images and multipole expansion
Week 6 Exam 1
Week 7 Magnetostatics and special relativity
Week 8 Magnetic fields
Week 9 Magnetic fields; Maxwell's laws; magnetic properties of materials
Week 10 Exam 2; magnetized materials
WEEK #
Week 11 Circuits
SES #
TOPICS
32
Exam 2
33
Ampere's law in magnetized materials (PDF)
34
Bound current; ferromagnetism (PDF)
35
Circuits (PDF)
36
Circuits; undriven RC circuits; Thevenin's theorem (PDF)
37
Thevenin's theorem (cont.); Ohm's law; Faraday's law; Lenz's law (PDF)
38
Alternating current circuits (PDF)
39
Inductance (PDF)
40
Undriven RLC circuits (PDF)
41
Driven RLC circuits; Ladder impedance (PDF)
42
Maxwell's equations (PDF)
43
Poynting vector; Maxwell stress tensor (PDF)
44
Conservation of momentum; Minkowski force (PDF)
45
Review for exam 3 (PDF)
46
Exam 3
47
Electromagnetic waves (PDF)
48
Electromagnetic waves (cont.) (PDF)
49
Topics for next week; relativity (PDF)
50
Faraday tensor; Maxwell; General relativity (PDF)
51
Quantum (PDF)
52
Schrodinger equation (PDF)
Week 12 Circuits (cont.)
Week 13 Maxwell; momentum
Week 14 Electromagnetic waves
Week 15 Advanced topics in relativity; quantum
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