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Electricity and Magnetism: Maxwell’s Equations
Electricity and Magnetism: Maxwell’s Equations
(65 Lectures Available)
S#
Lecture
Course
Institute
Instructor
Discipline
1
L23v1: Electromotive Force
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
2
L23v4: Faraday's Law
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
3
L24v1: Bar Magnet Through a Coil of Wire
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
4
L24v2: Magnet Through a Copper Pipe
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
5
L24v3: Lenz's Law
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
6
L24v4: Jumping Ring
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
7
L25v2: Right Hand Rule to Find the Direction of the Induced Electric Field
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
8
L25v3: Lenz's Law to Find the Direction of Induced Electric Field
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
9
L25v4: Induced Electric Field Outside a Solenoid with Changing Current
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
10
L25v5: Eddy Current Braking
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
11
L26v1: Mutual Inductance
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
12
L26v4: Self Inductance
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
13
L27v1: Energy in and Inductor
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
14
L27v2: Magnetic Energy Density
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
15
L27v3: Calculating Capacitance and Inductance in Two Ways
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
16
L28v1: Charge on a Capacitor in an RC Circuit
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
17
L28v2: Inductors in a Circuit
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
18
L28v3: Current in a LR Circuit
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
19
L28v4: Time Constants
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
20
L28v5: LR Circuit Demo
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
21
L29DD1: Analogy of LC Circuits to Simple Harmonic Motion
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
22
L29v1: Review of Simple Harmonic Motion
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
23
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
24
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
25
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
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Basic and Health Sciences
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Engineering
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English
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