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Micro and Nanophotonics for Semiconductor Infrared Detectors electronic resource Towards an Ultimate Uncooled Device / by Zoran Jakšić.

By: Jakšić, Zoran [author.]Contributor(s): SpringerLink (Online service)Material type: TextTextPublication details: Cham : Springer International Publishing : Imprint: Springer, 2014Description: XXI, 258 p. 152 illus., 41 illus. in color. online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9783319096742Subject(s): engineering | Microwaves | Optical materials | Materials Science | Optical and Electronic Materials | Microwaves, RF and Optical Engineering | Optics, Optoelectronics, Plasmonics and Optical Devices | Nanotechnology and MicroengineeringDDC classification: 620.11295 | 620.11297 LOC classification: TA1750-1750.22Online resources: Click here to access online
Contents:
From the Contents: Part I Introduction- A Path to an Ideal Photonic Detector -- Infrared Detector Performance and Main Figures of Merit -- Classification of IR Detectors -- Part II Photon Management -- Nonimaging and Imaging Optical Concentrators -- Refractive Concentrators -- Part III Charge Carrier Management (Thermal Noise Engineering) -- Nonequilibrium Suppression of Auger Generation-Recombination -- Limits of Nonequilibrium Detector Operation.
In: Springer eBooksSummary: The advent of microelectromechanic system (MEMS) technologies and nanotechnologies  has resulted in a multitude of structures and devices with ultracompact dimensions and with vastly enhanced or even completely novel properties. In the field of photonics it resulted in the appearance of new paradigms, including photonic crystals that exhibit photonic bandgap and represent an optical analog of semiconductors and metamaterials that have subwavelength features and may have almost arbitrary values of effective refractive index, including those below zero. In addition to that, a whole new field of plasmonics appeared, dedicated to the manipulation with evanescent, surface-bound electromagnetic waves and offering an opportunity to merge nanoelectronics with all-optical circuitry. In the field of infrared technologies MEMS and nanotechnologies ensured the appearance of a new generation of silicon-based thermal detectors with properties vastly surpassing the conventional thermal devices. However, another family of infrared detectors, photonic devices based on narrow-bandgap semiconductors, has traditionally been superior to thermal detectors. Literature about their micro and nanophotonic enhancement has been scarce and scattered through journals. This book offers the first systematic approach to numerous different MEMS and nanotechnology-based methods available for the improvement of photonic infrared detectors and points out to a path towards uncooled operation with the performance of cryogenically cooled devices. It is shown that a vast area for enhancement does exists and that photonic devices can readily keep their leading position in infrared detection. The various methods and approaches described in the book are also directly applicable to different other types of photodetectors like solar cells, often with little or no modification.
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From the Contents: Part I Introduction- A Path to an Ideal Photonic Detector -- Infrared Detector Performance and Main Figures of Merit -- Classification of IR Detectors -- Part II Photon Management -- Nonimaging and Imaging Optical Concentrators -- Refractive Concentrators -- Part III Charge Carrier Management (Thermal Noise Engineering) -- Nonequilibrium Suppression of Auger Generation-Recombination -- Limits of Nonequilibrium Detector Operation.

The advent of microelectromechanic system (MEMS) technologies and nanotechnologies  has resulted in a multitude of structures and devices with ultracompact dimensions and with vastly enhanced or even completely novel properties. In the field of photonics it resulted in the appearance of new paradigms, including photonic crystals that exhibit photonic bandgap and represent an optical analog of semiconductors and metamaterials that have subwavelength features and may have almost arbitrary values of effective refractive index, including those below zero. In addition to that, a whole new field of plasmonics appeared, dedicated to the manipulation with evanescent, surface-bound electromagnetic waves and offering an opportunity to merge nanoelectronics with all-optical circuitry. In the field of infrared technologies MEMS and nanotechnologies ensured the appearance of a new generation of silicon-based thermal detectors with properties vastly surpassing the conventional thermal devices. However, another family of infrared detectors, photonic devices based on narrow-bandgap semiconductors, has traditionally been superior to thermal detectors. Literature about their micro and nanophotonic enhancement has been scarce and scattered through journals. This book offers the first systematic approach to numerous different MEMS and nanotechnology-based methods available for the improvement of photonic infrared detectors and points out to a path towards uncooled operation with the performance of cryogenically cooled devices. It is shown that a vast area for enhancement does exists and that photonic devices can readily keep their leading position in infrared detection. The various methods and approaches described in the book are also directly applicable to different other types of photodetectors like solar cells, often with little or no modification.

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