| Titre : | High Performance Materials and Devices for High-Speed Electronic Systems |
| Auteurs : | F. Jain, Auteur ; C. Broadbridge, Auteur |
| Type de document : | document électronique |
| Editeur : | Singapore : World scientific, 2018 |
| ISBN/ISSN/EAN : | 978-981-327-629-1 |
| Format : | 1 vol. (viii-141 p.) / couv. ill. / 24 cm |
| Langues: | Anglais |
| Index. décimale : | 620.11 (Matériaux) |
| Catégories : | |
| Mots-clés: | Electronic Systems |
| Résumé : |
In this review volume, the editors have included the state-of-the-art research and development in nano composites, and optical electronics written by experts in the field. In addition, it also covers applications for emerging technologies in High-Speed Electronics.In summary, topics covered in this volume includes various aspects of high performance materials and devices for implementing High-Speed Electronic systems. |
| Note de contenu : |
Contents: • Characterization of Ge Quantum Dot Optical Waveguides for High Speed Optical Modulators. • Electrophoretic Deposition of 10B Nano/Micro Particles in Deep Silicon Trenches for the Fabrication of Solid State Thermal Neutron Detectors. • Dual Quantum Dot Superlattice. • Circuits and Simulation of Quaternary SRAM Using Quantum Dot Channel Field Effect Transistors. • Modeling and Fabrication of GeOx-Ge Cladded Quantum Dot Channel (QDC) FETs on Poly-Silicon. • Quantum Dot Floating Gate Nonvolatile Random Access Memory Using Ge Quantum Dot Channel for Faster Erasing. • Design of an Inductorless Power Converter with Maximizing Power Extraction for Energy Harvesting. • High-Speed Pulsed Fiber Ring Laser Using Photonic Crystal Fiber.as Adjustable Strain Platforms for Metamorphic Semiconductor Devices. • Dynamical X-Ray Diffraction Analysis of a GaAs/In0.3Ga0.7As Single Quantum Well Grown on a GaAs (001) Substrate. • The Measurement of Microwave Absorption Characteristics of Nanocomposites Using a Coaxial Line Technique. • Additively Manufactured Inkjet-/3D-/4D-Printed Wireless Sensors Modules. • All-Optical Logic Gates Based on Quantum-Dot Semiconductor Optical Amplifier. |
| Côte titre : |
F8/12796 |
| En ligne : | https://www.worldscientific.com/doi/epdf/10.1142/11156 |
Exemplaires (1)
| Cote | Support | Localisation | Disponibilité |
|---|---|---|---|
| F8/12796 | Livre | Bibliothèque Fac. de Technologie | Disponible |
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