05359nam 2200697Ia 450 991102012810332120170810195444.09786612350108978128235010612823501029780470994535047099453397804709945280470994525(CKB)1000000000687362(EBL)470699(OCoLC)609849719(SSID)ssj0000309524(PQKBManifestationID)11239740(PQKBTitleCode)TC0000309524(PQKBWorkID)10267669(PQKB)11387841(MiAaPQ)EBC470699(PPN)148463614(Perlego)2774951(EXLCZ)99100000000068736220070104d2008 uy 0engur|n|---|||||txtccrSilicon photonics the state of the art /Graham T. ReedChichester Wileyc20081 online resource (354 p.)Description based upon print version of record.9780470025796 0470025794 Includes bibliographical references and index.SILICON PHOTONICS; Contents; Foreword; About the Editor; List of Contributors; Acknowledgements; 1 Introduction: The Opto-Electronic Integrated Circuit; 1.1 A Few Words About History; 1.2 The Possibilities for OEICs; 1.3 The Present Status of OEICs; 1.4 Silicon-based GeSn and SiGeSn Technology; 1.5 OEICs for the Near, Mid and Far Infrared; 1.6 Opto-Eletronic Integration with Ultimate CMOS and Post CMOS; 1.7 Nanophotonics Integrated with Nanoelectronics; 1.8 Conclusion; References; 2 Silicon Photonic Waveguides; 2.1 Introduction; 2.2 Planar Waveguides; 2.3 Rib Waveguides; 2.4 Strip Waveguides2.5 Coupling to Small Silicon Waveguides2.6 Novel Silicon Waveguide Structures; 2.6.1 Free-standing Waveguides; 2.6.2 Hollow Waveguides; 2.7 Summary and Conclusions; References; 3 Silicon-based Photonic Crystal Structures: From Design to Realization; 3.1 Theory of Photonic Crystals and Photonic Bandgap Structures; 3.1.1 Analogy Between Photonic and Semiconductor Crystals; 3.1.2 Analyzing Photonic Bandgap Structures; 3.1.3 Doping of Photonic Crystals; 3.1.4 Waveguides and Nano-cavities in Photonic Crystals; 3.2 Fabrication and Characterization of Photonic Crystals3.2.1 Planar/2D Photonic Crystal Fabrication3.2.2 3D Photonic Crystal Fabrication; 3.3 Overview of Photonic Bandgap Applications in Silicon Photonic Integrated Circuits; 3.4 Silicon Photonic Crystal Dispersion-based Applications; 3.4.1 Non-channel Waveguide; 3.4.2 A Unidirectional Emitter; 3.4.3 Sub-surface Silicon Optical Bus Based on Three-dimensional Photonic Crystals; 3.4.4 Dispersion-based Variable Beam Splitter; 3.4.5 Photonic Crystal Analog-to-digital Converter; 3.5 Conclusions; References; 4 Optical Modulators in Silicon Photonic Circuits; 4.1 Introduction4.2 Mechanisms for Optical Modulation in Silicon4.2.1 Absorption; 4.2.2 Optical Modulation Mechanisms in Silicon; 4.3 A Brief History of Silicon Modulator Designs; 4.4 Conclusion; References; 5 Silicon Lasers; 5.1 Introduction; 5.2 Why Bulk Silicon Cannot Amplify Light; 5.2.1 Physics of Optical Gain in Bulk Silicon; 5.3 Approach 1: Quantum Confinement; 5.4 Approach 2: Erbium Doping and Other Approaches; 5.4.1 Hybrid Integration of III-V and Silicon; 5.5 Approach 3: Raman Effect; 5.5.1 Physics of Raman Scattering in Silicon; 5.5.2 Limitation of Active Carrier Removal Using a p-n Junction5.5.3 Electrical Power Dissipation Caused by Active Carrier Sweep-out5.5.4 Raman Wavelength Conversion; 5.5.5 Comparison of Raman with Other Optical Nonlinearities in Silicon; 5.6 Experimental Realization of Raman-based Silicon Photonic Devices; 5.7 GeSi Raman Devices; 5.8 Mid-wave IR (MWIR) Silicon Photonics; 5.8.1 Prospects of Mid-infrared Silicon Raman Devices; 5.9 Energy Harvesting in Silicon Raman and Other Nonlinear Optical Devices; 5.10 Summary; References; 6 Optical Detection Technologies for Silicon Photonics; 6.1 Introduction; 6.2 Photodetector Theory6.2.1 Band-edge Photo-excitation of Charge CarriersSilicon photonics is currently a very active and progressive area of research, as silicon optical circuits have emerged as the replacement technology for copper-based circuits in communication and broadband networks. The demand for ever improving communications and computing performance continues, and this in turn means that photonic circuits are finding ever increasing application areas. This text provides an important and timely overview of the 'hot topics' in the field, covering the various aspects of the technology that form the research area of silicon photonics. With contributions froOptoelectronic devicesSiliconOptical propertiesPhotonicsOptoelectronic devices.SiliconOptical properties.Photonics.621.38152Reed Graham T286110MiAaPQMiAaPQMiAaPQBOOK9911020128103321Silicon photonics4416933UNINA02718nam 22006974a 450 991095853050332120251116191501.01-135-88776-41-135-88775-61-280-09900-30-203-44421-30-203-42711-410.4324/9780203427118 (CKB)1000000000358572(EBL)182933(OCoLC)437056176(SSID)ssj0000359241(PQKBManifestationID)11259332(PQKBTitleCode)TC0000359241(PQKBWorkID)10381805(PQKB)10504544(MiAaPQ)EBC182933(Au-PeEL)EBL182933(CaPaEBR)ebr10166515(CaONFJC)MIL9900(OCoLC)1000430494(EXLCZ)99100000000035857220030421d2003 uy 0engur|n|---|||||txtccrEighteenth-century keyboard music /edited by Robert L. Marshall2nd ed.New York Routledge20031 online resource (431 p.)Routledge studies in musical genresDescription based upon print version of record.1-138-17132-8 0-415-96642-6 Includes bibliographical references and index.Book Cover; Title; Contents; Preface; Acknowledgments; Second Edition; Contributors; The Instruments; Aspects of Performance Practice; Johann Sebastian Bach; French Masters; Domenico Scarlatti; Carl Philipp Emanuel Bach; Johann Christian Bach and the Early Classical Italian Masters; Haydn's Solo Keyboard Music; Mozart's Solo Keyboard Music; Mozart's Keyboard Concertos; Early Beethoven; Index18th-Century Piano Music focuses on the core composers of the 18th century repertoire. Each chapter is written by a well-known scholar in the field, and includes history, musical examples, and analysis.Routledge studies in musical genres.18th-century keyboard musicKeyboard instrument music18th centuryHistory and criticismPerformance practice (Music)History18th centuryKeyboard instrumentsKeyboard instrument musicHistory and criticism.Performance practice (Music)HistoryKeyboard instruments.786/.09/033Marshall Robert Lewis937963MiAaPQMiAaPQMiAaPQBOOK9910958530503321Eighteenth-century keyboard music4491778UNINA