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Principles of Nanophotonics (Optics and Optoelectronics)
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Principles of Nanophotonics (Optics and Optoelectronics)  Principles of Nanophotonics (Optics and Optoelectronics) By Motoichi Ohtsu, Kiyoshi Kobayashi, Tadashi Kawazoe, Takashi Yatsui, Makoto Naruse Publisher: Taylor & Francis Number Of Pages: 248 Publication Date: 2008-06-06 ISBN-10 / ASIN: 1584889721 ISBN-13 / EAN: 9781584889724 Binding: Hardcover download:http://ifile.it/hn309oi/pnp1584889721.rar Contents Preface........................................................................................ix Authors..........................................................................................xi 1 Introduction.........................................................................................1 1.1 Modern Optical Science and Technology. and the Diffraction Limit...............................................................................1 1.2 Breaking Through the Diffraction Limit.....................................................4 1.3 Nanophotonics and Its True Nature.......................................................... 10 1.4 Some Remarks...................................................................................... 15 References.............................................................................................. 16 2 Basis of Nanophotonics.................................................................... 19 2.1 Optical Near-Fields and Effective Interactions as a Base for Nanophotonics...................... 19 2.1.1 Relevant Nanometric Subsystem and Irrelevant Macroscopic Subsystem............... 21 2.1.2 P Space and Q Space.........................................................................22 2.1.3 Effective Interaction Exerted in the Nanometric Subsystem........................... 24 2.2 Principles of Operations of Nanophotonic Devices Using Optical Near-Fields...................29 2.2.1 Energy States of a Semiconductor QD...........................................29 2.2.2 Dipole-Forbidden Transition........................................................... 37 2.2.3 Coupled States Originating in Two Energy Levels......................42 2.2.4 Basic Ideas of Nanophotonic Devices............................................46 2.2.5 Fundamental Tool for Describing Temporal Behavior................50 2.2.6 Exciton Population Dynamics and Nanophotonic Logic Operation...........................................................................................66 2.3 Principles of Nanofabrication Using Optical Near Fields.......................78 2.3.1 Field Gradient and Force..................................................................78 2.3.2 Near-Field Nanofabrication and Phonon’s Role...........................80 2.3.3 Lattice Vibration in Pseudo One-Dimensional System...............85 2.3.4 Optically Excited Probe System and Phonons..............................89 2.3.5 Localization Mechanism of Dressed Photons..............................96 References.................................................................................................. 103 3 Nanophotonic Devices.................................................................... 109 3.1 Excitation Energy Transfer........................................................................ 109 3.2 Device Operation........................................................................................ 116 3.2.1 Nanophotonic and Gate................................................................. 117 3.2.2 Nanophotonic NOT Gate............................................................... 121 3.3 Interconnection with Photonic Devices...................................................125 3.4 Room-Temperature Operation.................................................................. 129 3.4.1 Using III-V Compound Semiconductor QDs.............................. 130 3.4.2 Using a ZnO Nanorod with Quantum Wells............................. 132 References.................................................................................................. 135 4 Nanophotonic Fabrication.............................................................. 139 4.1 Adiabatic Nanofabrication......................................................................... 139 4.2 Nonadiabatic Nanofabrications................................................................ 145 4.2.1 Nonadiabatic Near-Field Optical CVD........................................ 145 4.2.2 Nonadiabatic Near-Field Photolithography................................ 151 4.3 Self-Assembling Method Via Optical Near-Field Interactions............ 154 4.3.1 Regulating the Size and Position of Nanoparticles. Using Size-Dependent Resonance................................................ 155 4.3.2 Size-, Position-, and Separation-Controlled Alignment of Nanoparticles................ 159 References............................................................................................. 162 5 Fundamentals of Nanophotonic Systems..................................... 165 5.1 Introduction..................................................................................... 165 5.2 Optical Excitation Transfer and System Fundamentals........................ 167 5.2.1 Optical Excitation Transfer Via Optical Near-Field Interactions and Its Functional Features...... 167 5.2.2 Parallel Architecture Using Optical Excitation Transfer.......... 169 5.2.2.1 Memory-Based Architecture........................................... 169 5.2.2.2 Global Summation Using Near-Field Interactions....... 170 5.2.3 Interconnections for Nanophotonics........................................... 172 5.2.3.1 Interconnections for Nanophotonics............................. 172 5.2.3.2 Broadcast Interconnects................................................... 173 5.2.4 Signal Transfer and Environment: Tamper Resistance............. 177 5.3 Hierarchy in Nanophotonics and Its System Fundamentals............... 180 5.3.1 Physical Hierarchy in Nanophotonics and Functional Hierarchy..................... 180 5.3.2 Hierarchical Memory Retrieval.................................................... 182 5.3.3 Analysis and Synthesis of Hierarchy in Nanophotonics:Angular Spectrum-Based Approach.... 185 5.3.3.1 Analysis of Hierarchy Based on Angular Spectrum.............................. 185 5.3.3.2 Synthesis of Hierarchy Based on Angular Spectrum................... 188 5.3.4 Hierarchy Plus Localized Energy Dissipation: Traceable Memory........................... 190 5.3.4.1 Localized Energy Dissipation......................................... 190 5.3.4.2 Engineering Shape of Metal Nanostructures for Hierarchy................................. 191 5.4 Summary and Discussion......................................................................... 193 References................................................................................................ 194 Appendix A Projection Operator........................................................ 199 Appendix B Effective Operator and Effective Interaction.............. 201 Appendix C Elementary Excitation Mode and Electronic Polarization...................... 205 Appendix D Minimal Coupling and Multipolar Hamiltonians.......... 211 Appendix E Transformation from Photon Base to Polariton Base.................................... 219 The Theory and Applications of Nanophotonics Devices, Fabrication, and Systems Coauthored by the developer of nanophotonics, Principles of Nanophotonics outlines physically intuitive concepts of the subject using a novel theoretical framework that differs from conventional wave optics. It probes far-reaching physical insights into the local electromagnetic interaction in the nanometric subsystem composed of electrons and photons. After reviewing the background, history, and current status of research and development in nanophotonics and related technologies, the book presents a unique theoretical model to describe the interactions among nanometric material systems via optical near-fields. It also evaluates a nonadiabatic fabrication process using this theoretical model. The authors then explore nanophotonic devices and fabrication techniques and provide examples of qualitative innovation. The final chapter looks at how the assembly of nanophotonic devices produces a nanophotonic system. Realize the Great Potential of Nanophotonics Nanophotonics is on its way to revolutionizing various applications in devices, fabrications, and information and communication systems. Promoting further exploration in the field, this book helps you understand the theory behind nanophotonics and how it can be applied to devices and systems. |
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