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PHYS 201 - Fundamentals of Physics II

Lecture 11 - Lenz's and Faraday's Laws. The electric effect of a changing magnetic field is described using Faraday's Law. The direction of the current so generated is given by Lenz's Law. The operation and energy accounting of the generator are described. The concept of inductance is introduced. The Betatron is described as an example of Faraday's Law. Self and mutual inductance are introduced. The energy density in a magnetic field is derived. (from oyc.yale.edu)

Lecture 11 - Lenz's and Faraday's Laws

Time Lecture Chapters
[00:00:00] 1. Review of Lenz and Faraday's Law
[00:25:39] 2. The Power Generator
[00:37:47] 3. Mutual and Self Inductance
[01:04:11] 4. Energy Density of a Magnetic Field

References
PHYS 201: Lecture 11 - Lenz's and Faraday's Laws
Instructor: Professor Ramamurti Shankar. Resources: Faraday and Lenz - A Loop in Two Frames [pdf]. Problem Set 5 and Solutions [pdf]. Transcript [html]. Audio [mp3]. Download Video [mov].

Go to the Course Home or watch other lectures:

Lecture 01 - Electrostatics
Lecture 02 - Electric Fields
Lecture 03 - Gauss's Law I
Lecture 04 - Gauss's Law and Application to Conductors and Insulators
Lecture 05 - The Electric Potential and Conservation of Energy
Lecture 06 - Capacitors
Lecture 07 - Resistance
Lecture 08 - Circuits and Magnetism I
Lecture 09 - Magnetism II
Lecture 10 - Ampere's Law
Lecture 11 - Lenz's and Faraday's Laws
Lecture 12 - LCR Circuits - DC Voltage
Lecture 13 - LCR Circuits - AC Voltage
Lecture 14 - Maxwell's Equations and Electromagnetic Waves I
Lecture 15 - Maxwell's Equations and Electromagnetic Waves II
Lecture 16 - Ray or Geometrical Optics I
Lecture 17 - Ray or Geometrical Optics II
Lecture 18 - Wave Theory of Light
Lecture 19 - Quantum Mechanics I: Key experiments and wave-particle duality
Lecture 20 - Quantum Mechanics II
Lecture 21 - Quantum Mechanics III
Lecture 22 - Quantum Mechanics IV: Measurement theory, states of definite energy
Lecture 23 - Quantum Mechanics V: Particle in a box
Lecture 24 - Quantum Mechanics VI: Time-dependent Schrodinger Equation
Lecture 25 - Quantum Mechanics VII: Summary of postulates and special topics