SCCI Digital Library and Forum
Electricity and Magnetism: Maxwell’s Equations
| S# | Lecture | Course | Institute | Instructor | Discipline |
|---|---|---|---|---|---|
| 51 |
L29v2: Introduction to LC Circuits
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 52 |
L34v1: Maxwell's Equations in Vacuum
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 53 |
L38v7: Red Laser Interference and Diffraction
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 54 |
L29v3: LC Circuit and Mass on a Spring Analogy
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 55 |
L34v2: Plane Wave Solution to Maxwell's Equations in Vacuum
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 56 |
The Story Continues – the Higgs Particle
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 57 |
L29v4: LC Oscillator Equation
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 58 |
L36DD1: Proof of Energy Conservation with the Poynting Vector
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 59 |
W14PS2: Worked Example – Poynting Vector for a Solenoid
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 60 |
L36v1: Conservation Laws
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 61 |
W14PS3: Worked Example – Poynting Vector for a Resistor
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 62 |
L36v2: Poynting Vector
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 63 |
L36v3: Direction of the Poynting Vector
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 64 |
Why Study Electromagnetism
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
| 65 |
L36v6: Power and Poynting Vector from a Radially Symmetric Source
|
Electricity and Magnetism: Maxwell’s Equations | MIT | Peter Dourmashkin, Krishna Rajagopal, Dr. Kerstin Perez, Dr. Analia Barrantes, Dr. Michelle Tomasik, Prof.Robert Redwine | Basic and Health Sciences |
- « Previous
- 1
- 2
- 3