图书简介

Preface; Acknowledgements; Chapter 1: Introduction; 1.1 Introduction to Nanophotonics; 1.2 Nanophotonics : Scope; 1.3 Introduction to Nanostructures; 1.4 Novel Phenomena in Nanophotonics: A Brief Outline; 1.5 Applications of Nanophotonics; 1.6 Problems of Integration; Chapter 2: Basic Properties of Semiconductors; 2.1 Introduction; 2.2 Band Structure; 2.3 Density of States; 2.4 Doping; 2.5 Carrier Concentration; 2.6 Carrier Concentration; 2.7 Excess Carriers and Recombination; 2.8 Excitons; 2.9 Alloys and Heterojunctions; 2.10 Quantum Structures; 2.11 Strained Layers; Chapter 3: Macroscopic Theory of Optical Processes; 3.1 Introduction; 3.2 Optical Constants; 3.3 Phase and Group Velocities; 3.4 Susceptibility of a Material: a Classical Model; 3.5 Einstein’s Model for Light-Matter Interaction; Chapter 4: Photons and Electron-photon Interactions; 4.1 Introduction; 4.2 Wave Equation in a Rectangular Cavity; 4.3 Quantization of the Radiation Field; 4.4 Time Dependent Perturbation Theory; 4.5 Interaction of an Electron with the Electromagnetic Field; 4.6 Second Order Perturbation Theory; Chapter 5: Electron Photon Interactions in Bulk Semiconductors; 5.1 Introduction; 5.2 Absorption Processes in Semiconductors; 5.3 Fundamental Absorption in Direct gap; 5.4 Intervalence Band Absorption; 5.5 Free Carrier Absorption; 5.6 Recombination and Luminescence; 5.7 NonradiativeRecombination; 5.8 Carrier Effect on Absorption and Refractive Index; 5.9 Gain in Semiconductors; Chapter 6: Optical Processes in QWs; 6.1 Introduction; 6.2 Optical Processes in QWs; 6.3 Interband Absorption; 6.4 Intersubband Absorption; 6.5 Recombination in QWs; 6.6 Loss Processes in QWs; 6.7 Gain in QWs; 6.8 Strained QW Lasers; Chapter 7: Excitons in Bulk Semiconductors and QWs; 7.1 Introduction; 7.2 Excitons in Bulk Semiconductors; 7.3 Excitonic Processes in QWs; 7.4 Line Broadening Mechanisms for 2D Excitons; 7.5 Effect of Electric Field in Semiconductors; 7.6 Excitonic Characteristics in Fractional Dimensional Space; Chapter 8: Nanowires; 8.1 Introduction; 8.2 Quantum Wires: Preliminaries; 8.3 Excitonic Processes in QWRs; 8.4 Classification of Nanowires; 8.5 Growth of QWRs; 8.6 Nanowires; 8.7 Properties of NWRs; 8.8 Applications of NWRs; Chapter 9: Nanoparticles; 9.1 Introduction; 9.2 Quantum Dots; 9.3 QD Growth Mechanisms and Structures; 9.4 Zero Dimensional Systems; 9.5 Deviation from Simple Theory: Effect of Broadening; 9.6 QD Lasers : Structure and Gain Calculation; 9.7 Intersubband Transitions; 9.8 Excitonic Processes in QDs; 9.9 Classification of Nanocrystals; 9.10 Synthesis of Nanocrystals; 9.11 Core-Shell Structures; 9.12 Bright and Dark Excitons; 9.13 Biexcitons and Trions; 9.14 Applications; Chapter 10: Microcavity; 10.1 Introduction; 10.2 Cavity Fundamentals; 10.3 Fabry-Perot Resonators; 10.4 Bragg Gratings and Bragg Mirrors; 10.5 Ring Resonators; 10.6 Whispering Gallery Mode Resonators; 10.7 Wave Propagation in Periodic Structures: Photonic Crystals; 10.8 Micropillar; 10.9 Characteristics of Microcavity; Chapter 11: Cavity Quantum Elecrodynamics; 11.1 Introduction; 11.2 Zero-Point Energy and Vacuum Field; 11.3 Control of Spontaneous Emission; 11.4 Mode Density in Ideal Cavities; 11.5 Experimental Observation of Purcell Effect; 11.6 Strong Light-Matter Coupling; 11.7 Jaynes-Cummins Model; 11.8 Microcavities in CQED Experiments; 11.9 Applications; 11.10 Microcavity Laser; Chapter 12: Bose Einstein Condensation; 12.1 Introduction; 12.2 Elements of Bose Einstein Condensation; 12.3 BEC in Semiconductors; 12.4 Bulk Excitons; 12.5 Indirect Excitons in Coupled QWs; 12.6 Polariton; 12.7 Polariton Lasers; 12.8 Modeling of Electrically Driven Polariton Laser; Chapter 13: Surface Plasmons; 13.1 Introduction; 13.2 Basic Concepts; 13.3 Surface Plasmon Polaritons at Metal/Insulator Interfaces; 13.4 Excitation Mechanism; 13.5 Materials; 13.6 Length Scales in Noble Metals; 13.7 Metal-insulator Based Plasmonics-photonics; 13.8 All Semiconductor Plasmonics; 13.9 Plasmonic Properties of Semiconductors; 13.10 Components: source, modulators, waveguides, detector; 13.11 Application of Plasmonics in VLSI, Data Centres and Supercomputers; 13.12 Applications of Surface Plasmons in Basic Science and Characterization; 13.13 Intersubband Plasmons; Chapter 14: Spasers and Plasmonic Nanolasers; 14.1 Introduction; 14.2 Early Investigations on SP Amplification; 14.3 Models for Noginov et al Experiment; 14.4 Semiconductor Spasers and Plasmonic Nanolasers; 14.5 Theoretical Models by Khurgin and Sun; 14.6 Current Theoretical Models and Experiments; 14.7 Further Developments; Chapter 15: Optical Metamaterials; 15.1 Introduction; 15.2 Left Handed Material with Negative RI; 15.3 Structures for Microwaves; 15.4 Perfect Lens; 15.5 NIR with Positive Permittivity and Permeability; 15.6 Low Loss Plasmonic Metamaterial; 15.7 Semiconductor Metamaterials; 15.8 Metasurfaces; 15.9 Beam Steering; Chapter 16: Nanolasers; 16.1 Introduction; 16.2 Parameters of Lasers; 16.3 Progress in Nanolasers; 16.4 Threshold Pump Power of Nanolasers: Purcell Effect; 16.5 Intrinsic Merit of Nanolasers; 16.6 Optical Interconnect; 16.7 Metal Based Nanolasers

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