Photodetectors (2nd Ed.) Materials, Devices and Applications Woodhead Publishing Series in Electronic and Optical Materials Series
Coordonnateur : Nabet Bahram
Every bit of information that circulates the internet across the globe is a pulse of light, that at some point will need to be converted to an electric signal in order to be processed by the electronic circuitry in our data centers, computers, and cell phones. Photodetectors (PD?s) perform this conversion with ultra high speed and efficiency, in addition to being ubiquitously present in many other devices ranging from the mundane TV remote controls, to ultra high resolution instrumentation used in Laser Interferometer Gravitational Wave Observatory (LIGO) that reach the edge of the universe and measure gravitational waves. The second edition of "Photodetectors" fully updates the popular first edition with updated information covering the state-of-the-art in modern photodetectors.
The 2nd edition starts with basic metrology of photodetectors and common figures-of-merit to compare various devices. It follows with chapters that discuss single-photon detection with Avalanche Photodiodes; organic photodetectors that can be inkjet printed; and silicon-germanium PDs popular in burgeoning field of Silicon Photonics. Internationally recognized experts contribute chapters on one-dimensional, nanowire, PDs as well as high speed zero-dimensional, quantum dot, versions that increase the spectral span as well as speed and sensitivity of PDs and can be produced on various substrates. Solar-blind PDs that operate in harsh environments such as deep space, or rocket engines, are reviewed and new devices in GaN technology . Novel Plasmonic PDs, as well as devices which employ micro-plasma of confined charge in order to make devices that overcome speed limitation of transfer of electronic charge, are covered in other chapters. Using different, novel technologies, CMOS compatible devices are described in two chapters, and ultra high speed PDs that use low-temperature-grown GaAs (LT-GaAs) to detect fast THz signals are reviewed in another chapter. Photodetectors used in application areas of Silicon-Photonics and Microwave-Photonics are reviewed in final chapters of this book.
All chapters are of a review nature, providing a perspective of the field before concentrating on particular advancements. As such, the book should appeal to a wide audience that ranges from those with general interest in the topic, to practitioners, graduate students and experts who are interested in the state-of-the-art in photodetection.
1. Photodetectors for silicon photonic integrated circuits
2. Hi-speed high-sensitivity no bias photo detector based on bilayer charge plasma
3. Carbon nanotube and graphene photonic devices
4. Nanowire enabled photodetection
5. Low temperature grown gallium arsenide (LT-GaAs) high speed detectors
6. Plasmonic photodetectors
7. Organic photodetectors
8. Silicon photomultipliers (SiPM)
Part II: Applications of Photodetectors
9. Photodetectors for microwave photonics
10. CMOS- integrated waveguide photodetectors for communications applications
11. Silicon based single-photon avalanche diode (SPAD) technology for low-light and high-speed applications
12. Terahertz (THz) detectors
13. Resonant cavity enhanced photodetectors: theory, design and modeling
14. Unconventional photo capacitor with giant light induced capacitance enhancement
- Addresses various photodetector devices from ultra high speed to ultra high sensitivity, capable of operation in harsh environments
- Considers a range of applications for this important technology, including silicon photonics and photonic integrated circuits
- Includes discussions of detectors based on reduced dimensional systems such as quantum wells, nanowires, and quantum dots, as well as travelling wave, and plasmonic detectors
Date de parution : 02-2023
Ouvrage de 512 p.
15.2x22.8 cm
Thèmes de Photodetectors :
Mots-clés :
A photomultiplier tube (PMT); And electro-optic sampling; And multispectral photonics; Avalanche diodes; Avalanche processes in silicon; Bandgap; CMOS compatibility; CMOS imaging; Carrier lifetime and ultrafast carrier dynamics; Charge plasma; Charge transport; Communication and measurement; Communications; Complementary metal-oxide-semiconductor technology; Data/telecom; Detector; Digital photon counting (DPC); Electronic noise; Emerging semiconductors; Energy relaxation; Equivalent circuits; Gallium nitride; Geiger avalanche photodiode (GAPD); Germanium hetero-epitaxy; Graphene and UV and NIR; Group-IV photonics; High speed; High-speed photodetector; High-temperature; III–V on silicon; Image intensifier (I2); Imaging; InAs; Infrared photodetector; Interconnect; Large area electronics; Lidar; Light trapping; Low-temperature-grown GaAs; MSM diodes; Metallic silicide and Schottky barrier; Metasurfaces; Metrology; Millimeter wave; Multichannel plate (MCP); Nanophotonics; Nanowire integration; Nanowire photodetectors; Optical photodetectors; Optoelectronics; Organic electronics; Organic photodetectors; Organic photodiodes and organic photoconductors; Organic semiconductors; PIN diodes; Photocurrent; Photodetector; Photodetectors; Photodiodes; Plasmonics; Plasmonics; Print transfer; Printed electronics; Quantum dot; Semiconductor; Silicon; Silicon photomultiplier (SiPM); Silicon photonics and integrated optoelectronics; Silicon waveguide; Silicon-germanium receivers; Single-photon avalanche diode (SPAD); Single-photon counting; Source; Spectroscopy; Terahertz; Thin-film photodetectors; Time and spatial resolution; Time-of-flight ranging; Two-dimensional gas; Ultraviolet
