Nano-optoelectronic sensors and devices : nanophotonics from design to manufacturing /

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Nanophotonics has emerged as a major technology and applications domain, exploiting the interaction of light-emitting and light-sensing nanostructured materials. These devices are lightweight, highly efficient, low on power consumption, and are cost effective to produce. The authors of this book hav...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Xi, Ning (Editor ), Lai, King Wai Chiu (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam ; Boston : Elsevier/William Andrew, 2011.
Colección:Micro & nano technologies.
Temas:
Optical detectors.
Optoelectronic devices.
Nanotechnology.
Nanophotonics.
Détecteurs optiques.
Dispositifs optoélectroniques.
Nanophotonique.
Nanotechnologie.
TECHNOLOGY & ENGINEERING > Sensors.
Nanophotonics
Nanotechnology
Optical detectors
Optoelectronic devices
Acceso en línea:Texto completo (Requiere registro previo con correo institucional)
Tabla de Contenidos:
  • Front cover; Nano-Optoelectronic Sensors and Devices:Nanophotonics from Design toManufacturing; Copyright; Table of Contents; Preface; Acknowledgments; About the Editors; List of Contributors; Chapter 1. Introduction; 1.1 Overview; 1.2 Impact of Nanomaterials; 1.3 Challenges and Difficulties in Manufacturing Nanomaterials-Based Devices; 1.3.1 Role of Microfluidics; 1.3.2 Role of Robotic Nanoassembly; 1.4 Summary; References; Chapter 2. Nanomaterials Processing for Device Manufacturing; 2.1 Introduction; 2.2 Characteristics of Carbon Nanotubes
  • 2.3 Classification of Carbon Nanotubes using Microfluidics2.3.1 Dielectrophoretic Phenomenon on CNTs; 2.3.2 Experimental Results: Separation of Semiconducting CNTs; 2.4 Deposition of CNTs by Microrobotic Workstation; 2.5 Summary; References; Chapter 3. Design and Generation ofDielectrophoretic Forcesfor Manipulating CarbonNanotubes; 3.1 Overview; 3.2 Dielectrophoretic Force Modeling; 3.2.1 Modeling of Electrorotation for Nanomanipulation; 3.2.2 Dynamic Modeling of Rotational Motion of Carbon Nanotubes for Intelligent Manufacturing of CNT-Based Devices
  • 3.2.3 Dynamic Effect of Fluid Medium on Nano Particles by Dielectrophoresis3.3 Theory for Microelectrode and Electric Field Design for Carbon Nanotube Applications; 3.3.1 Microelectrode Design; 3.3.2 Theory for Microelectrode Design; 3.4 Electric Field Design; 3.5 Carbon Nanotubes Application-Simulation Results; 3.5.1 Dielectrophoretic Force: Simulation Results; 3.5.2 Electrorotation (Torque): Simulation Results; 3.5.3 Rotational Motion of Carbon Nanotubes: Simulation Results; 3.6 Summary; References; Chapter 4. Atomic ForceMicroscope-Based Nanorobotic System for Nanoassembly
  • 4.1 Introduction to AFM and Nanomanipulation4.1.1 AFM's Basic Principle; 4.1.2 Imaging Mode of AFM; 4.1.3 AFM-Based Nanomanipulation; 4.2 AFM-Based Augmented Reality System; 4.2.1 Principle for 3D Nanoforce Feedback; 4.2.2 Principle for Real-Time Visual Feedback Generation; 4.2.3 Experimental Testing and Discussion; A. Nanomanipulation with Augmented Reality System; B. Discussion: Limitations of Augmented Reality System; 4.3 Augmented Reality System Enhanced by Local Scan; 4.3.1 Local Scan Mechanism for Nanoparticle; 4.3.2 Local Scan Mechanism for Nanorod
  • 4.3.3 Nanomanipulation with Local Enhanced Augmented Reality SystemA. Manipulation of Nanoparticles; B. Manipulation of Nanorods; 4.4 CAD-Guided Automated Nanoassembly; 4.5 Modeling of Nanoenvironments; 4.6 Automated Manipulation of CNT; 4.7 Summary; References; Chapter 5. On-Chip Band Gap Engineering of Carbon Nanotubes; 5.1 Introduction; 5.2 Quantum Electron Transport Model; 5.2.1 Nonequilibrium Green's Functions; 5.2.2 Poisson's Equation and Self-Consistent Algorithm; 5.3 Electrical Breakdown Controller of a CNT; 5.3.1 Extended Kalman Filter for Fault Detection

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