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Electricity and Magnetism: Maxwell’s Equations

(65 Lectures Available)

S# Lecture Course Institute Instructor Discipline
51
  • L37DD1: Energy Momentum and Wavelength of a Photon
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
  • L37v1: Radiation Pressure
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
  • L37v2: Momentum Carried by Electromagnetic Radiation
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
  • L37v3: Perfectly Absorbing and Reflecting Surfaces
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
  • L38v1: Interference
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
  • L38v2: Two Slit Interference
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
  • L38v3: Red Laser Interference
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
  • L38v4: 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
59
  • L38v5: Red Laser 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
60
  • L38v6: Diffraction and Interference
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
  • 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
62
  • 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
63
  • 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
64
  • 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
65
  • 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

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