| Description |
1 online resource (xii, 339 pages) |
| Contents |
Cover -- Half Title -- Title Page -- Copyright Page -- Contents -- Preface -- 1. Introduction -- 1.1 Si Photonics -- 1.2 Si-Based Photonics -- 1.3 Book Content -- 2. Band Structure and Optical Properties -- 2.1 Bonding Lengths in a Diamond/Zincblende Lattice -- 2.2 Dielectric Function -- 2.3 Absorption Processes -- 2.4 Direct Group IV Semiconductors -- 3. Planar Waveguides -- 3.1 Modes in the Slab Waveguide -- 3.2 Strip Waveguides and Rib Waveguides -- 3.3 Loss in a Silicon Optical Waveguide -- 3.4 Polarization Dependence of Silicon Waveguides -- 3.5 Summary -- 4. Microring Resonators |
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4.1 Introduction -- 4.2 Principle of the Microring Resonator -- 4.2.1 Single Microring -- 4.2.2 Cascaded Microrings -- 4.2.2.1 Transfer matrix units -- 4.2.2.2 Series-coupled microring resonators -- 4.2.2.3 Parallel-coupled microring resonators -- 4.3 Optical Properties of Microring Resonators -- 4.3.1 Properties of Amplitude -- 4.3.1.1 Single microring -- 4.3.1.2 Cascaded microrings -- 4.3.2 Properties of Phase -- 4.4 Design of Microring Resonators -- 4.4.1 Waveguide Design -- 4.4.2 Coupler Design -- 4.4.3 Internal Loss -- 4.5 Fabrication and Measurement of Microring Resonators |
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4.5.1 Fabrication Flow -- 4.5.2 Electron Beam Lithography -- 4.5.3 Dry Etching Process -- 4.5.4 Silicon Oxide Growing -- 4.5.5 Measurement -- 4.6 Applications of Microring Resonators -- 4.6.1 Optical Filter -- 4.6.2 Nonlinear Optical Devices -- 4.6.3 Optical Buffer -- 4.7 Summary -- 5. Optical Couplers -- 5.1 Introduction -- 5.2 Spot-Size Converters -- 5.2.1 Tapered Spot-Size Converter -- 5.2.2 Inverted Tapered Spot-Size Converter -- 5.2.3 Slot-Waveguide Spot-Size Converter -- 5.3 Prism Couplers -- 5.3.1 Inverted Prism Coupler -- 5.3.2 Graded Index Half-Prism Coupler -- 5.4 Grating Couplers |
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5.4.1 Grating Coupler with a Vertical Coupling Structure -- 5.4.2 Horizontal Dual Grating-Assisted Coupler -- 5.5 Conclusion -- 6. Photonic Crystals -- 6.1 Introduction -- 6.2 Master Equation -- 6.3 Calculation Methods -- 6.3.1 PWE Method -- 6.3.2 FDTD Method -- 6.4 Silicon-Based PC Slab -- 6.4.1 Important Points about the SOI PC Slab -- 6.4.2 Fabrication of Silicon-Based PC Slab -- 6.5 SOI PC Devices -- 6.5.1 SOI PC Waveguides -- 6.5.2 SOI PC Microcavities -- 6.5.3 SOI PC Filters -- 6.6 Conclusions -- 7. Slow Light in a Silicon-Based Waveguide -- 7.1 Introduction -- 7.2 Concept |
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7.3 Slow Light in Microring Resonator Waveguides -- 7.3.1 Single-Microring Resonator -- 7.3.2 SCISSOR Configuration Microring Resonators -- 7.3.3 CROW Configuration Microring Resonators -- 7.3.4 Experimental Progress -- 7.4 Slow Light in Photonic Crystals -- 7.4.1 Generation of Slow Light in a Photonic Crystal Waveguide -- 7.4.2 Experimental Verification of Slow Light in Photonic Crystals -- 7.5 Conclusion -- 8. Light Emitters -- 8.1 Bandgap Emission Mechanisms -- 8.1.1 Indirect Semiconductor Transitions -- 8.1.2 Brillouin Zone Folding from the Superlattice |
| Summary |
Silicon photonics has evolved rapidly as a research topic with enormous application potential. The high refractive index contrast of silicon-on-insulator (SOI) shows great promise for submicron waveguide structures suited for integration on the chip scale in the near-infrared region. Ge- and GeSn-Si heterostructures with different elastic strain levels already provide expansion of the spectral range, high-speed operation, efficient modulation and switching of optical signals, and enhanced light emission and lasing. This book focuses on the integration of heterostructure devices with silicon photonics. The authors have attempted to merge a concise treatment of classical silicon photonics with a description of principles, prospects, challenges, and technical solution paths of adding silicon-based heterostructures. The book discusses the basics of heterostructure-based silicon photonics, system layouts, and key device components, keeping in mind the application background. Special focus is placed on SOI-based waveguide configurations and Ge- and GeSn-Si heterostructure devices for light detection, modulation, and light emission and lasing. The book also provides an overview of the technological and materials science challenges connected with integration on silicon. The first half of the book is mainly for readers who are interested in the topic because of its increasing importance in different fields, while the latter half covers different device structures for light emission, detection, modulation, extension of the wavelength beyond 1.6 m, and lasing, as well as future challenges |
| Bibliography |
Includes bibliographical references and index |
| Notes |
8.1.3 Localization of Wave Functions by Quantum Structures and Porous Si |
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Erich Kasper obtained his PhD in physics from the University of Graz, Austria. From 1971 to 1993, he worked in the research institutes of Telefunken, AEG, and Daimler Benz, Germany, where he led research on silicon-based devices and technologies. He joined the University of Stuttgart, Germany, as professor in 1993. From 1993 to 2008, he was head of the Institute of Semiconductors, University of Stuttgart. He was also guest professor at HUST, China, and guest lecturer at MU Leoben, Austria, and he coordinated interdisciplinary research projects on behalf of the German Research Council until 2016. Dr. Kasper has coauthored more than 500 peer-reviewed papers and edited many books. His current research interests focus on benefits of Ge/Si heterostructures for high-quantum-efficiency photovoltaics and energy harvesting, millimeter-wave imaging and near-field radar for medical applications, primary building blocks and integration concepts for silicon-based photonics, and infrared vision for automotive purposes and climate research. Jinzhong Yu is professor in the University of the Chinese Academy of Sciences, China. He graduated from the University of Science and Technology of China in 1965 and received his PhD in engineering from Osaka University, Japan, in 1991. From 1965 to 2008, he was with the Institute of Semiconductors, Chinese Academy of Sciences. He has received various awards from the State and the Chinese Academy of Sciences, including the "Teaching Model in University of Chinese Academy of Sciences" in 2018. He has also written a few books, such as Semiconductor Photonics and Semiconductor Optoelectronics Technology, in Chinese and more than 400 papers. Prof. Yu has long been engaged in semiconductor photonics research and has led key projects on the study of III-V compound lasers and Si-based optical waveguides and photonic integration |
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Online resource; title from digital title page (viewed on August 18, 2020) |
| Subject |
Silicon -- Optical properties
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Photonics.
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Semiconductors.
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Semiconductors
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semiconductor.
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SCIENCE -- Life Sciences -- General.
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TECHNOLOGY -- Lasers.
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TECHNOLOGY -- Material Science.
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Photonics
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Semiconductors
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Silicon -- Optical properties
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| Form |
Electronic book
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| Author |
Yu, Jinzhong, 1943- author
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| ISBN |
135164498X |
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9781315156514 |
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1315156512 |
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9789814303255 |
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9814303259 |
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9781351644983 |
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