E-Book, Englisch, Band 2015, 454 Seiten
Reihe: Reviews in Plasmonics
Geddes Reviews in Plasmonics 2015
1. Auflage 2016
ISBN: 978-3-319-24606-2
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
E-Book, Englisch, Band 2015, 454 Seiten
Reihe: Reviews in Plasmonics
ISBN: 978-3-319-24606-2
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
Reviews in Plasmonics 2015, the second volume of the new book series from Springer, serves as a comprehensive collection of current trends and emerging hot topics in the field of Plasmonics and closely related disciplines. It summarizes the year's progress in surface plasmon phenomena and its applications, with authoritative analytical reviews in sufficient detail to be attractive to professional researchers, yet also appealing to the wider audience of scientists in related disciplines of Plasmonics.
Reviews in Plasmonics offers an essential source of reference material for any lab working in the Plasmonics field and related areas. All academics, bench scientists, and industry professionals wishing to take advantage of the latest and greatest in the continuously emerging field of Plasmonics will find it an invaluable resource.
Autoren/Hrsg.
Weitere Infos & Material
1;Preface;6
2;Contents;8
3;Chapter 1: Surface Plasmon Polariton Assisted Optical Switching in Noble Metal Nanoparticle Systems: A Sub-Band Gap Approach;10
3.1;1.1 Introduction;10
3.1.1;1.1.1 A Percolative Pathway for Electrical Transport;13
3.1.2;1.1.2 A Tunnelling Route to Electrical Transport;16
3.1.3;1.1.3 A Propagative Surface Plasmon for Electrical Transport;19
3.2;References;23
4;Chapter 2: Modeling and Interpretation of Hybridization in Coupled Plasmonic Systems;27
4.1;2.1 Introduction;28
4.2;2.2 Coupled Mode Model Applied to Interacting Plasmon Modes;29
4.3;2.3 Definition of the Complex Valued Extinction of Nanoparticle Assemblies;32
4.4;2.4 Numerical Extraction of Resonance Parameters;33
4.5;2.5 Eigenmodes of Single Spheres;36
4.6;2.6 Hybrid Modes in Dimers;40
4.6.1;2.6.1 Hybrid Modes and Their Energetic Behavior;40
4.6.2;2.6.2 Near-Field Enhancement;45
4.7;2.7 Weak and Strong Coupling in Quadrumers;46
4.7.1;2.7.1 Weak Coupling in Small Size Systems;46
4.7.2;2.7.2 Hybridization and Fano-Like Resonances in Strongly Coupled SystemsFano-like resonances;50
4.8;2.8 Conclusion;55
4.9;References;56
5;Chapter 3: Radiolytically Synthesized Noble Metal Nanoparticles: Sensor Applications;58
5.1;3.1 Introduction;59
5.2;3.2 Synthesis of Ag/Au Nanoparticles;60
5.3;3.3 Characterization of Metal Nanoparticles;61
5.4;3.4 Applications of Radiation Synthesized NobleMetal Nanoparticles: LSPR Based Sensor Applications;62
5.4.1;3.4.1 PVP Stabilized-Au NPs for H2O2 Estimation;63
5.4.2;3.4.2 PVP Stabilized-Au NPs for Hg2+ Estimation;64
5.4.3;3.4.3 PVP Stabilized-Ag NPs for Uric Acid Estimation;65
5.4.3.1;3.4.3.1 Estimation of Uric Acid in Bovine and Human Serum Samples;68
5.4.4;3.4.4 PMA Stabilized-Ag NPs for Dopamine Estimation;69
5.4.4.1;3.4.4.1 Estimation of Dopamine in Presence of Ascorbic AcidAscorbic acid (AA);70
5.5;3.5 Conclusion;71
5.6;References;71
6;Chapter 4: Construction, Modeling, and Analysis of Transformation-Based Metamaterial Invisibility Cloaks;75
6.1;4.1 Introduction;76
6.2;4.2 Theory of Controlling EM Fields by Coordinate Transformation;80
6.2.1;4.2.1 Derivation of Medium Parameter Tensors under Coordinate Transformation;80
6.2.2;4.2.2 Redirection of Optical Paths by Coordinate and Medium Transformation;84
6.3;4.3 Theory of Spherical Transformation-Based Metamaterial Cloaks;86
6.3.1;4.3.1 Construction of LinearLinear spherical metamaterial cloaks Spherical Metamaterial Cloaks;86
6.3.2;4.3.2 Construction of NonlinearNonlinear spherical metamaterial cloaks Spherical Metamaterial Cloaks;88
6.4;4.4 Conformal Cubical Transformation-Based Metamaterial Cloaks;89
6.5;4.5 Higher Order EM Modeling and Analysis of Metamaterial Cloaks;91
6.6;4.6 Results and Discussion;94
6.6.1;4.6.1 Examples of Spherical Transformation-Based Metamaterial Cloaks;94
6.6.2;4.6.2 Examples of Cubical Transformation-Based Metamaterial Cloaks;98
6.7;4.7 Conclusions;104
6.8;References;106
7;Chapter 5: Interaction of Surface Plasmon Polaritons with Nanomaterials;108
7.1;5.1 Introduction;109
7.2;5.2 Dispersion Properties of Surface Plasmon Polaritons;109
7.2.1;5.2.1 Dispersion Relation Over a Single Metal Surface;109
7.2.2;5.2.2 Dispersion Relation of SPPs in Double Metal Surface Configuration;111
7.2.3;5.2.3 Surface Plasmons in Multilayer Thin Films Configuration;113
7.3;5.3 Absorption of Surface Plasmons Polaritons by Metallic Nanoparticles;116
7.4;5.4 Laser Mode Conversion into SPPs in a Metal Coated Optical Fiber;119
7.4.1;5.4.1 Dispersion Relations of Body Waves and Surface Plasmon Polaritons;120
7.4.2;5.4.2 Mode Conversion;123
7.5;5.5 Electron Acceleration by Surface Plasmon Polaritons;125
7.5.1;5.5.1 Double Metal Configuration;126
7.5.2;5.5.2 Single Metal Configuration;127
7.6;5.6 Surface Plasmon Excitations in Surface Enhanced RamanSpectroscopy;129
7.7;5.7 Surface Plasmon Plasmon Applications in Sensing and Solar Cell Technology;132
7.8;References;133
8;Chapter 6: Ultrafast Response of Plasmonic Nanostructures;135
8.1;6.1 Introduction;136
8.2;6.2 Surface Plasmons in Metal Nanoparticles;138
8.3;6.3 Ultrafast Optical Response of Photoexcited Metal Nanoparticles;143
8.3.1;6.3.1 Tuning Between Ultrafast PB and PA in Gold Nanorods by Selective Probing Near LSP Resonance;149
8.3.2;6.3.2 Light Controlled Reversible Switching Between Ultrafast PB and PA in Gold Nanorods;152
8.4;6.4 Ultrafast Optical Nonlinearities of Metal Nanoparticles;155
8.4.1;6.4.1 Surface Plasmon Resonance Tuned Optical Nonlinearities;155
8.4.2;6.4.2 Metal Nanoclusters with Improved Ultrafast Nonlinearity;157
8.5;6.5 Direct Observation of Surface Vibrations in Nanoparticles;163
8.6;6.6 Summary and Outlook;167
8.7;References;168
9;Chapter 7: Graphene-Based Ultra-Broadband Slow-Light System and Plamonic Whispering-Gallery-Mode Nanoresonators;172
9.1;7.1 Introduction;172
9.2;7.2 Validity of the Zero-Thickness Graphene Monolayer Model;174
9.3;7.3 Surface Conductivity of Graphene;177
9.4;7.4 Analysis of the Propagation Constant of the Plasmons Along the Graphene Monolayer;179
9.5;7.5 Nanofocusing of the Mid Infrared Electromagnetic Field on the Gradient Chemical Potential Distributed Graphene Monolayer;181
9.6;7.6 Ultra-Broadband Rainbow Capture and Releasing Along Gradient Chemical Potential Distributed Graphene Monolayer;183
9.7;7.7 Tunable Plasmonic Whispering-Gallery-Mode Properties of the Graphene Monolayer Coated Dielectric Nanowire and Nanodisks;187
9.8;References;191
10;Chapter 8: Fano Resonance in Plasmonic Optical Antennas;194
10.1;8.1 Introduction;195
10.2;8.2 Fano Resonance in Optical Nanoantennas;196
10.3;8.3 Analytical Model for Optical Nanoantenna Clusters;197
10.3.1;8.3.1 Electrodynamics Coupling Model for Nanoclusters;197
10.3.2;8.3.2 Superradiant and Subradiant Coupling Matrix Elements;201
10.3.3;8.3.3 Analysis of Optical Directivity Properties;203
10.4;8.4 Transmission and Reflection Analysis;204
10.4.1;8.4.1 Superradiant Mode Analysis;204
10.4.2;8.4.2 Fano Resonance Analysis;207
10.5;8.5 Element Optimization;209
10.5.1;8.5.1 Directivity Analysis;209
10.5.2;8.5.2 Bandwidth Analysis;211
10.6;8.6 Directivity Analysis;213
10.7;8.7 Mass Spring Model;216
10.8;8.8 Circuit Model;218
10.8.1;8.8.1 Plasmonic Nanosphere Circuit Model;218
10.8.2;8.8.2 Fano Resonance Circuit Model;219
10.9;8.9 Conclusion;223
10.10;References;224
11;Chapter 9: Elongated Nanostructured Solar Cells with a Plasmonic Core;228
11.1;9.1 Introduction;228
11.2;9.2 Experimental Procedures and Setups;231
11.2.1;9.2.1 Sample Fabrication;231
11.2.2;9.2.2 Solar Simulator;232
11.2.3;9.2.3 Spectral Response;234
11.2.4;9.2.4 Angle and Polarization Resolved Measurements;235
11.2.5;9.2.5 Specular Reflection and Scattering;235
11.3;9.3 ExperimentaHydrogenated amorphous silicon (a-Si:H)l Study of a Silver Nanoneedle Plasmonic Core Inside an Elongated a-Si:H...;236
11.4;9.4 FDTD Simulations on the Ag Nanoneedle Inside a a-Si:H Core-Shell Structure;241
11.4.1;9.4.1 The Finite-Difference Time Domain MethodFinite-difference time domain (FDTD) method;241
11.4.2;9.4.2 Simulation Details;243
11.4.3;9.4.3 FDTD Simulation Results and Comparison with Experiment;244
11.5;9.5 Future Possibilities;248
11.6;References;249
12;Chapter 10: Controlled Assembly of Plasmonic Nanostructures Templated by Porous Anodic Alumina Membranes;252
12.1;10.1 Introduction;252
12.2;10.2 Highly Ordered Plasmonic NanostructuresPorous anodic alumina (PAA) membranes Templated by PAA Membranes;254
12.2.1;10.2.1 Plasmonic Nanostructures Templated by the Pore Surface of PAA Membranes;255
12.2.2;10.2.2 Plasmonic Nanostructures Templated by the Bottom Surface of PAA Membranes;257
12.2.3;10.2.3 Plasmonic Nanostructures Patterned by Single Step Direct Imprint Process;259
12.3;10.3 Applications;262
12.3.1;10.3.1 Surface-Enhanced Raman Scattering (SERS) SensingSurface-enhanced Raman scattering (SERS) sensing;262
12.3.2;10.3.2 Fluorescence Process Tailoring;266
12.4;10.4 Summary;273
12.5;References;274
13;Chapter 11: Origin of Shifts in the Surface Plasmon Resonance Frequencies for Au and Ag Nanoparticles;278
13.1;11.1 Introduction;278
13.1.1;11.1.1 Red ShiftRed shiftRed shift of SPR Frequency: Spillout EffectRed shift;279
13.1.2;11.1.2 Blue ShiftBlue shift of SPRBlue shift Frequency: Screening EffectScreening effect;284
13.1.3;11.1.3 Blue Shift of SPR Frequency: Quantum EffectQuantum effect;288
13.2;References;296
14;Chapter 12: Quantum Plasmonics: From Quantum Statistics to Quantum Interferences;298
14.1;12.1 Introduction;298
14.2;12.2 From Quantum Optics to Quantum Plasmonics;300
14.3;12.3 Quantum Statistics of Surface Plasmon Polaritons in Metallic Stripe Waveguides;302
14.4;12.4 Quantum Interference in the Plasmonic Hong-Ou-Mandel Effect;307
14.5;12.5 Conclusions;313
14.6;References;314
15;Chapter 13: Lasers and Plasmonics: SPR Measurements of Metal Thin Films, Clusters and Bio-Layers;317
15.1;13.1 Introduction;318
15.2;13.2 Experimental Details;321
15.2.1;13.2.1 Thin Films Deposition Technique;323
15.2.1.1;13.2.1.1 Introduction to Physical Vapour Deposition (PVD);324
15.2.1.2;13.2.1.2 Thermal Evaporation;324
15.2.2;13.2.2 Thin Films Preparation;325
15.2.3;13.2.3 Thin Films Characterization (Morphology);326
15.2.3.1;13.2.3.1 Atomic Force Microscopy (AFM);326
15.2.3.1.1;Introduction;326
15.2.3.1.2;Principle of Operation;326
15.3;13.3 Results and Discussion (Section I);330
15.3.1;13.3.1 Single Layer Films;330
15.3.2;13.3.2 Double Layer Films;332
15.4;13.4 Summary (Section I);335
15.5;13.5 Results and Discussion (Section II);336
15.6;13.6 Summary (Section II);339
15.7;References;339
16;Chapter 14: Plasmon Assisted Luminescence in Rare Earth Doped Glasses;341
16.1;14.1 Glasses and Glass Ceramics;343
16.2;14.2 Trivalent Rare Earth Ions Doped Glasses;347
16.2.1;14.2.1 Radiative Properties and Judd-Ofelt Theory;349
16.2.2;14.2.2 Energy Transfers and Cooperative Process;352
16.2.3;14.2.3 Non-linear and Upconversion Processes;353
16.3;14.3 Optical Properties of Metallic Nanoparticles;354
16.3.1;14.3.1 Interaction of Light with Nanoparticles;355
16.3.2;14.3.2 Preparation and Observation of Metallic Nanoparticles;357
16.3.3;14.3.3 Surface Enhanced Raman and Fluorescence Spectroscopy (SERS, SEFS);360
16.4;14.4 Rare Earth Doped Glasses Embedded with Metallic NPs;361
16.4.1;14.4.1 Eu3+-Doped;363
16.4.2;14.4.2 Er3+-Doped;366
16.4.3;14.4.3 Nd3+-Doped;370
16.4.4;14.4.4 Sm3+-Doped;370
16.4.5;14.4.5 Dy3+-Doped;373
16.4.6;14.4.6 Tm3+-Doped;373
16.4.7;14.4.7 Tb3+-Doped;375
16.4.8;14.4.8 Pr3+-Doped;377
16.4.9;14.4.9 Ho3+-Doped;378
16.5;14.5 Summary;378
16.6;References;380
17;Chapter 15: Surface Enhanced Fluorescence by Plasmonic Nanostructures;389
17.1;15.1 Introduction;390
17.2;15.2 SEF Principles;391
17.2.1;15.2.1 Principles of Fluorescence;391
17.2.2;15.2.2 Interaction of Fluorophores with Surface Plasmons;393
17.3;15.3 SEF from Various Geometrical Metallic Plasmonic Nanostructure;395
17.3.1;15.3.1 Fluorescence Enhancement from Periodical Metallic Plasmonic Nanostructure;395
17.3.1.1;15.3.1.1 Surface Enhanced Fluorescence from Nanograting Substrate;396
17.3.1.2;15.3.1.2 Surface Enhanced Fluorescence from Nanohole Arrays Substrate;397
17.3.1.3;15.3.1.3 Plasmon Enhanced Fluorescence from Nanoparticle Arrays Substrate;400
17.3.1.4;15.3.1.4 Plasmon Enhanced Fluorescence from Nanorod Arrays Substrate;402
17.3.2;15.3.2 Non-Periodical Metallic Plasmonic Nanostructure;402
17.3.2.1;15.3.2.1 Plasmon Enhanced Fluorescence from Metallic Silver Island Substrate;403
17.3.2.2;15.3.2.2 Surface Enhanced Fluorescence from Metallic Fractal-Like Substrate;403
17.3.2.3;15.3.2.3 Surface Enhanced Fluorescence from Deposited Metallic Nanoparticle Substrate;407
17.3.3;15.3.3 The Spacer and Wavelength Effect Towards the Fluorescence Enhancement;410
17.4;15.4 Conclusion;412
17.5;References;413
18;Chapter 16: Remote Spectroscopy Below the Diffraction Limit;418
18.1;16.1 Introduction;418
18.2;16.2 General Methods for Remote Spectroscopy on Silver Nanowires;421
18.3;16.3 Remote Excitation Surface Enhanced Raman Scattering (RE-SERS);422
18.4;16.4 Applications of RE-SERS: Live Cell RE-SERS Endoscopy;427
18.5;16.5 Remote Excitation of Single Molecule Fluorescence;432
18.6;16.6 Conclusions;439
18.7;References;439
19;Index;442
