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Lecture
Electromagnetic Waves and Laser Amplification
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Related lectures (29)
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Electromagnetic Waves: Basics and Applications
Explores the basics of optics, Maxwell's equations, wave propagation, and electromagnetic wave energy.
Electromagnetic waves
Explores the wave equation for electromagnetic fields, the propagation of electromagnetic waves, the fundamental velocity of light, and the concept of polarization.
Laser Fundamentals: Principles and Applications for Engineers
Covers the fundamentals of lasers, their historical development, and applications in engineering fields.
Electromagnetic Waves: Basics and Equations
Explores electromagnetic wave basics, wave equations, solutions, and energy transport in different mediums.
Electromagnetic Waves: Wave Equation and Maxwell's Equations
Explores the wave equation for electromagnetic waves, Maxwell's predictions, and the importance of polarization in defining wave properties.
E-M Wave Propagation in Materials: Loss-less vs. Lossy
Explores electromagnetic wave propagation in materials, including loss-less and lossy mediums, optical constants, and dispersion in glasses.
History of lasers: Lorentz model for atom/light interaction
Explores the history of lasers and the Lorentz model for atom-light interaction.
Electron oscillator model: absorption and refractive index
Explains how oscillating electron dipoles influence wave propagation and discusses absorption and refractive index.
Interaction of E-M Waves with Matter: Transmission, Absorption, Reflection
Explores how electromagnetic waves interact with matter, emphasizing transmission, absorption, and reflection.
Electron Oscillator Model: Lorentz Model
Introduces the electron oscillator model and its impact on electromagnetic wave propagation.
