Name: Active Plasmonics And Tuneable Plasmonic Metamaterials
Price: 586.37 PEN
Availability: InStock
Author: Anatoly V. Zayats, Stefan Maier
ISBN: 9781118092088

portada Active Plasmonics And Tuneable Plasmonic Metamaterials

Formato

Libro Físico

Editorial

Wiley

Autor

Anatoly V. Zayats, Stefan Maier

Tema

Optics & Photonics

Colección

Us Gr

N° páginas

344

Encuadernación

Cloth

Dimensiones

6 - 1 / 8 X 9 - 1 / 4 In

ISBN

1118092082

ISBN13

9781118092088

Categorías

Física atómica y molecular

Active Plasmonics And Tuneable Plasmonic Metamaterials

Anatoly V. Zayats, Stefan Maier (Autor) · Wiley · Cloth

Libro Nuevo

S/ 586,37

S/ 1.172,74

Ahorras: S/ 586,37

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Estado: Nuevo

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Reseña del libro "Active Plasmonics And Tuneable Plasmonic Metamaterials"

Preface Xiii Contributors Xvii 1 Spaser, Plasmonic Amplification, And Loss Compensation 1Mark I. Stockman 1. 1 Introduction To Spasers And Spasing 1 1. 2 Spaser Fundamentals 2 1. 2. 1 Brief Overview Of The Latest Progress In Spasers 5 1. 3 Quantum Theory Of Spaser 7 1. 3. 1 Surface Plasmon Eigenmodes And Their Quantization 7 1. 3. 2 Quantum Density Matrix Equations (Optical Bloch Equations) For Spaser 9 1. 3. 3 Equations For Cw Regime 11 1. 3. 4 Spaser Operation In Cw Mode 15 1. 3. 5 Spaser As Ultrafast Quantum Nanoamplifier 17 1. 3. 6 Monostable Spaser As A Nanoamplifier In Transient Regime 18 1. 4 Compensation Of Loss By Gain And Spasing 22 1. 4. 1 Introduction To Loss Compensation By Gain 22 1. 4. 2 Permittivity Of Nanoplasmonic Metamaterial 22 1. 4. 3 Plasmonic Eigenmodes And Effective Resonant Permittivity Of Metamaterials 24 1. 4. 4 Conditions Of Loss Compensation By Gain And Spasing 25 1. 4. 5 Discussion Of Spasing And Loss Compensation By Gain 27 1. 4. 6 Discussion Of Published Research On Spasing And Loss Compensations 29 Acknowledgments 33 References 33 2 Nonlinear Effects In Plasmonic Systems 41Pavel Ginzburg And Meir Orenstein 2. 1 Introduction 41 2. 2 Metallic Nonlinearities - - Basic Effects And Models 43 2. 2. 1 Local Nonlinearity - - Transients By Carrier Heating 43 2. 2. 2 Plasma Nonlinearity - - The Ponderomotive Force 45 2. 2. 3 Parametric Process In Metals 46 2. 2. 4 Metal Damage And Ablation 48 2. 3 Nonlinear Propagation Of Surface Plasmon Polaritons 49 2. 3. 1 Nonlinear Spp Modes 50 2. 3. 2 Plasmon Solitons 50 2. 3. 3 Nonlinear Plasmonic Waveguide Couplers 54 2. 4 Localized Surface Plasmon Nonlinearity 55 2. 4. 1 Cavities And Nonlinear Interactions Enhancement 56 2. 4. 2 Enhancement Of Nonlinear Vacuum Effects 58 2. 4. 3 High Harmonic Generation 60 2. 4. 4 Localized Field Enhancement Limitations 60 2. 5 Summary 62 Acknowledgments 62 References 62 3 Plasmonic Nanorod Metamaterials As A Platform For Active Nanophotonics 69Gregory A. Wurtz, Wayne Dickson, Anatoly V. Zayats, Antony Murphy, And Robert J. Pollard 3. 1 Introduction 69 3. 2 Nanorod Metamaterial Geometry 71 3. 3 Optical Properties 72 3. 3. 1 Microscopic Description Of The Metamaterial Electromagnetic Modes 72 3. 3. 2 Effective Medium Theory Of The Nanorod Metamaterial 76 3. 3. 3 Epsilon - Near - Zero Metamaterials And Spatial Dispersion Effects 79 3. 3. 4 Guided Modes In The Anisotropic Metamaterial Slab 82 3. 4 Nonlinear Effects In Nanorod Metamaterials 82 3. 4. 1 Nanorod Metamaterial Hybridized With Nonlinear Dielectric 84 3. 4. 2 Intrinsic Metal Nonlinearity Of Nanorod Metamaterials 85 3. 5 Molecular Plasmonics In Metamaterials 89 3. 6 Electro - Optical Effects In Plasmonic Nanorod Metamaterial Hybridized With Liquid Crystals 97 3. 7 Conclusion 98 References 99 4 Transformation Optics For Plasmonics 105Alexandre Aubry And John B. Pendry 4. 1 Introduction 105 4. 2 The Conformal Transformation Approach 108 4. 2. 1 A Set Of Canonic Plasmonic Structures 109 4. 2. 2 Perfect Singular Structures 110 4. 2. 3 Singular Plasmonic Structures 114 4. 2. 3. 1 Conformal Mapping Of Singular Structures 114 4. 2. 3. 2 Conformal Mapping Of Blunt - Ended Singular Structures 118 4. 2. 4 Resonant Plasmonic Structures 119 4. 3 Broadband Light Harvesting And Nanofocusing 121 4. 3. 1 Broadband Light Absorption 1214. 3. 2 Balance Between Energy Accumulation And Dissipation 123 4. 3. 3 Extension To 3D 125 4. 3. 4 Conclusion 1264. 4 Surface Plasmons And Singularities 127 4. 4. 1 Control Of The Bandwidth With The Vertex Angle 127 4. 4. 2 Effect Of The Bluntness 129 4. 5 Plasmonic Hybridization Revisited With Transformation Optics 130 4. 5. 1 A Resonant Behavior 131 4. 5. 2 Nanofocusing Properties 132 4. 6 Beyond The Quasi - Static Approximation 133 4. 6. 1 Conformal Transformation Picture 134 4. 6. 2 Radiative Losses 135 4. 6. 3 Fluorescence Enhancement 137 4. 6. 3. 1 Fluorescence Enhancement In The Near - Field Of Nanoantenna 138 4. 6. 3. 2 The Ct Approach 139 4. 7 Nonlocal Effects 142 4. 7. 1 Conformal Mapping Of Nonlocality 142 4. 7. 2 Toward The Physics Of Local Dimers 143 4. 8 Summary And Outlook 145 Acknowledgments 145 References 145 5 Loss Compensation And Amplification Of Surface Plasmon Polaritons 153Pierre Berini 5. 1 Introduction 153 5. 2 Surface Plasmon Waveguides 154 5. 2. 1 Unidimensional Structures 154 5. 2. 2 Bidimensional Structures 156 5. 2. 3 Confinement - Attenuation Trade - Off 156 5. 2. 4 Optical Processes Involving Spps 157 5. 3 Single Interface 157 5. 3. 1 Theoretical 157 5. 3. 2 Experimental 158 5. 4 Symmetric Metal Films 160 5. 4. 1 Gratings 160 5. 4. 2 Theoretical 160 5. 4. 3 Experimental 161 5. 5 Metal Clads 163 5. 5. 1 Theoretical 164 5. 5. 2 Experimental 164 5. 6 Other Structures 164 5. 6. 1 Dielectric - Loaded Spp Waveguides 164 5. 6. 2 Hybrid Spp Waveguide 165 5. 6. 3 Nanostructures 166 5. 7 Conclusions 166 References 167 6 Controlling Light Propagation With Interfacial Phase Discontinuities 171Nanfang Yu, Mikhail A. Kats, Patrice Genevet, Francesco Aieta, Romain Blanchard, Guillaume Aoust, Zeno Gaburro, And Federico Capasso 6. 1 Phase Response Of Optical Antennas 172 6. 1. 1 Introduction 172 6. 1. 2 Single Oscillator Model For Linear Optical Antennas 174 6. 1. 3 Two - Oscillator Model For 2D Structures Supporting Two Orthogonal Plasmonic Modes 176 6. 1. 4 Analytical Models For V - Shaped Optical Antennas 179 6. 1. 5 Optical Properties Of V - Shaped Antennas: Experiments And Simulations 183 6. 2 Applications Of Phased Optical Antenna Arrays 186 6. 2. 1 Generalized Laws Of Reflection And Refraction: Meta - Interfaces With Phase Discontinuities 186 6. 2. 2 Out - Of - Plane Reflection And Refraction Of Light By Meta - Interfaces 192 6. 2. 3 Giant And Tuneable Optical Birefringence 197 6. 2. 4 Vortex Beams Created By Meta - Interfaces 200 References 213 7 Integrated Plasmonic Detectors 219Pieter Neutens And Paul Van Dorpe 7. 1 Introduction 219 7. 2 Electrical Detection Of Surface Plasmons 221 7. 2. 1 Plasmon Detection With Tunnel Junctions 221 7. 2. 2 Plasmon - Enhanced Solar Cells 222 7. 2. 3 Plasmon - Enhanced Photodetectors 225 7. 2. 4 Waveguide - Integrated Surface Plasmon Polariton Detectors 232 7. 3 Outlook 236 References 237 8 Terahertz Plasmonic Surfaces For Sensing 243Stephen M. Hanham And Stefan A. Maier 8. 1 The Terahertz Region For Sensing 244 8. 2 Thz Plasmonics 2448. 3 Spps On Semiconductor Surfaces 245 8. 3. 1 Active Control Of Semiconductor Plasmonics 247 8. 4 Sspp On Structured Metal Surfaces 247 8. 5 Thz Plasmonic Antennas 249 8. 6 Extraordinary Transmission 253 8. 7 Thz Plasmons On Graphene 255 References 256 9 Subwavelength Imaging By Extremely Anisotropic Media 261Pavel A. Belov 9. 1 Introduction To Canalization Regime Of Subwavelength Imaging 261 9. 2 Wire Medium Lens At The Microwave Frequencies 264 9. 3 Magnifying And Demagnifying Lenses With Super - Resolution 2699. 4 Imaging At The Terahertz And Infrared Frequencies 272 9. 5 Nanolenses Formed By Nanorod Arrays For The Visible Frequency Range 276 9. 6 Superlenses And Hyperlenses Formed By Multilayered Metal - Dielectric Nanostructures 279 References 284 10 Active And Tuneable Metallic Nanoslit Lenses 289Satoshi Ishii, Xingjie Ni, Vladimir P. Drachev, Mark D. Thoreson, Vladimir M. Shalaev, And Alexander V. Kildishev 10. 1 Introduction 289 10. 2 Polarization - Selective Gold Nanoslit Lenses 290 10. 2. 1 Design Concept Of Gold Nanoslit Lenses 291 10. 2. 2 Experimental Demonstration Of Gold Nanoslit Lenses 29210. 3 Metallic Nanoslit Lenses With Focal - Intensity Tuneability And Focal Length Shifting 295 10. 3. 1 Liquid Crystal - Controlled Nanoslit Lenses 295 10. 3. 2 Nonlinear Materials For Controlling Nanoslit Lenses 300 10. 4 Lamellar Structures With Hyperbolic Dispersion Enable Subwavelength Focusing With Metallic Nanoslits 301 10. 4. 1 Active Lamellar Structures With Hyperbolic Dispersion 302 10. 4. 2 Subwavelength Focusing With Active Lamellar Structures 307 10. 4. 3 Experimental Demonstration Of Subwavelength Diffraction 308 10. 5 Summary 313 Acknowledgments 313 References 313