Explores electrical injection in semiconductors, transparency, laser oscillations, and edge-emitting laser diode design.
Explores the physics of photonic semiconductor devices, including LEDs, laser diodes, and quantum cascade lasers, emphasizing essential concepts and practical applications.
Covers Bragg mirrors, achieving reflectivities over 99% as an alternative to metallic mirrors, and their importance in light-matter interaction.
Explores optimizing quantum well laser diodes, edge emitting laser diodes' beam properties, optical gain measurements, laser mode spacing, and the Schawlow-Townes linewidth formula.
Explores the limitations of blue LEDs' efficiency and the efficiency droop in laser diodes.
Explores laser diodes' relaxation oscillations and their role in laser modulation, including random intensity noise effects and practical examples.
Explores the properties of semiconducting quantum nanostructures, focusing on generating entangled photon pairs for quantum communication.
Covers epitaxy, quantum nanostructures growth, and quantized energy levels computation.
Explores high Q optical microcavities, covering topics such as quality-factor, nonlinear properties, and cavity quantum optomechanics.
Covers the optical properties and applications of Stranski-Krastanov quantum dots, including confined electronic levels, single photon emission, and linewidth broadening.
