Lecture

Physics of Photonic Semiconductor Devices

Related lectures (32)

Physics of Photonic Semiconductor Devices: LEDs and Laser Diodes

Explores the limitations of blue LEDs' efficiency and the efficiency droop in laser diodes.

Explores electrical injection in semiconductors, transparency, laser oscillations, and edge-emitting laser diode design.

Light-Emitting Diodes: Efficiency and Applications

Explores the efficiency and applications of light-emitting diodes, covering carrier injection, spectral distribution, and key markets.

Efficient Visible Light Emitters

Explores the historical evolution and challenges of efficient visible light emitters, focusing on LED technology and the quest for 100%+ efficiency.

Semiconductor Physics: Fundamentals and Applications

Delves into the physics of semiconductors, exploring their properties and applications in electronics and optoelectronics.

Quantum Well Laser Diodes

Explores optimizing quantum well laser diodes, edge emitting laser diodes' beam properties, optical gain measurements, laser mode spacing, and the Schawlow-Townes linewidth formula.

Physics of Photonic Semiconductor Devices

Explores the physics of photonic semiconductor devices, including laser diodes, VCSELs, high-beta nanolasers, and quantum cascade lasers.

Nanostructured Devices: Low Dimensional Materials and Applications

Explores low-dimensional devices, focusing on nanowires and quantum dots, their properties, applications, and the challenges in their fabrication and performance.

Efficiency of LEDs: Fabrication and Comparison

Explores LED efficiency, fabrication, and comparison with alternative light sources, emphasizing the importance of the color rendering index.

Optical Communication Fundamentals

Covers the basics of optical communication, historical overview, fiber properties, modern developments, and technology drivers.

Solitons and Nonlinear Propagation

Explores solitons, nonlinear propagation, and their impact on optical communication systems.

Purcell Effect in Photonic Devices

Explores Lambertian emission, microcavity effect, Purcell effect, semiconductor micropillars, and two-dimensional photonic crystals.

Advancements in Blue and Deep Ultraviolet LEDs

Covers the development of blue and deep ultraviolet LEDs, emphasizing collaboration in research and their environmental benefits.

High-Speed Photodetectors: Applications in Telecommunication

Covers high-speed photodiodes and their critical role in telecommunication systems, including signal amplification and transmission techniques.

Spontaneous Emission in Quantum Wells

Explores spontaneous emission in quantum wells, electric field effects on optical transitions, and the quantum confined Stark effect.

Ultrafast Semiconductor Lasers

Explores the Mixel project, showcasing the importance of ultrafast semiconductor lasers and their diverse applications.

Quantum Nanostructures: Entangled Photon Sources

Explores the properties of semiconducting quantum nanostructures, focusing on generating entangled photon pairs for quantum communication.

Quantum Nanostructures: Growth and Fabrication

Covers epitaxy, quantum nanostructures growth, and quantized energy levels computation.

Laser Fundamentals: Applications and Technologies

Provides an overview of laser fundamentals, applications, and technologies relevant to engineering and manufacturing processes.

Introduction to Semiconductors and Nanostructures

Introduces the course on semiconductors and nanostructures, covering objectives, evaluation, and the importance of these materials in technology.