Lectures related to Electron Multiplying CCD: Principles and Applications

Avalanche Photodiodes: Principles and Applications

Discusses the principles, structures, and performance metrics of Avalanche Photodiodes in optical detection applications.

Photodiodes: Design and Optimization of Heterojunctions

Covers the design and optimization of photodiodes, focusing on enhancing performance through material selection and the importance of the depletion region.

Electron Bombarded CCD: Principles and Applications

Covers the principles and applications of electron bombarded charge-coupled devices for efficient single photon detection.

Optical Spectroscopy: Detectors and Quantum Efficiency

Explores optical spectroscopy, emphasizing photodetectors' efficiency and performance metrics.

Color Sensors: Photodiode Position and Performance

Examines how photodiode positioning affects the performance of color sensors.

Combining and comparing systems

Explores the combination of systems for radiation detection, from light collection to signal amplification using various semiconductor detectors.

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.

Light-Matter Interactions: Optical Detectors Overview

Provides an overview of light-matter interactions and their implications for optical detectors, including absorption, emission, and the characteristics of various semiconductor materials.

Single Photon Detection: Principles and Applications

Discusses the principles and applications of single photon detection using Single Photon Avalanche Diodes (SPAD).

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.

Quantum Efficiency: Photodiodes and Their Responsivity

Covers quantum efficiency and detectivity in photodiodes, focusing on their relationship with wavelength and practical implications in optical detection.

Quantum Structures: Band Gaps and Heterostructures

Covers the formation and properties of quantum wells and heterostructures in semiconductor materials.

Photon Detection: Efficiency and Coating

Explores high energy photon detection principles, efficiency, CCD detectors, Anti-Reflective coatings, and Signal to Noise ratio.

Light Emitting Diodes: Efficiency and Spectral Distribution

Explores light emission principles in LEDs, covering efficiency, spectral distribution, and stimulated emission importance.

Combining and comparing systems

Explores radiation detection principles, semiconductor systems, measurement chain, and detector comparisons.

Semiconductor Physics: Fundamentals and Applications

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

Diffusion Currents in Semiconductors: Principles and Equations

Covers diffusion currents in semiconductors, detailing their principles, equations, and interactions with drift currents.

PN Junctions and Heterostructures: Principles and Applications

Discusses the principles of pn junctions and heterostructures in semiconductor physics, focusing on their electrical characteristics and practical applications.

Photoelectric Effect: Principles and Applications

Covers the principles of photoemissive detectors and the photoelectric effect, detailing electron behavior in metals and semiconductors under different light conditions.

Diode Schottky and PN Heterojunctions: Band Structure Analysis

Covers the construction of band diagrams for Schottky diodes and PN heterojunctions in semiconductor physics.