This lecture covers the groundbreaking inventions in laser physics, including optical tweezers, chirped pulse amplification, and laser systems. It explores the theory and modern applications of lasers, such as trapping particles, amplifying optical pulses, and achieving high-intensity ultra-short pulses.
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Covers the basics of laser operation, including light-atom interaction and resonator design, discussing the quantum vs classical view of the atom and stimulated emission.
Covers the basic principles of laser operation, types of laser systems, noise characteristics, optical fibers, ultrafast lasers, and modern applications.
Covers the fundamental concepts of laser operation, including dispersion theory, gain and resonators, different types of laser systems, noise characteristics, optical fibers, ultrafast lasers, and nonlinear frequency conversion.