E-Book, Englisch, Band 2016, 245 Seiten
Reihe: Reviews in Plasmonics
Geddes Reviews in Plasmonics 2016
1. Auflage 2017
ISBN: 978-3-319-48081-7
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
E-Book, Englisch, Band 2016, 245 Seiten
Reihe: Reviews in Plasmonics
ISBN: 978-3-319-48081-7
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
Reviews in Plasmonics 2016, the third 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;7
3;1 Plasmonic Nanowire Waveguide for Deep Subwavelength Confinement;9
3.1;1.1 Introduction;9
3.2;1.2 Cylindrical Waveguide;10
3.3;1.3 Plasmonic Nanowire Waveguide;13
3.4;1.4 Hybrid Plasmonic Waveguide;16
3.5;1.5 Conclusions;20
3.6;References;21
4;2 Plasmon-Enhanced Fluorescence of Rare Earth Nanocrystals;23
4.1;2.1 Introduction;24
4.2;2.2 Dopant-Controlled Synthesis of Upconversion Rare Earth Nanocrystals for Improved Fluorescence;25
4.3;2.3 Synthesis of Rare Earth Nanocrystal Shells on Plasmonic Nanostructures;29
4.3.1;2.3.1 Synthesis of Metal/Oxide Core/Shell Nanocrystals;29
4.3.2;2.3.2 Synthesis of Au NR/Vanadate Core/Shell Nanocrystals;29
4.3.3;2.3.3 Synthesis of Au Nanoparticle/Vanadate Core/Shell Nanocrystals;32
4.4;2.4 Plasmon-Enhanced Upconversion Fluorescence of a Single Rare Earth Nanocrystal;34
4.5;2.5 Fluorescence Tunability of Rare Earth Upconversion Nanocrystals by Coupling with Plasmonic Nano Arrays;35
4.6;2.6 Conclusions;39
4.7;References;39
5;3 Sensing Through Surface Plasmon Resonance Technique;46
5.1;3.1 Principle of Surface Plasmon Resonance (SPR);47
5.2;3.2 Techniques Based on SPR for Sensing Applications;49
5.2.1;3.2.1 Angular Interrogation Based Sensor;49
5.2.2;3.2.2 Wavelength Interrogation Based Sensor;53
5.2.3;3.2.3 SPR Imaging Based Sensor;54
5.3;3.3 Sensing Applications of SPR;55
5.4;3.4 Conclusion;57
5.5;References;58
6;4 Fractal Plasmonic Nanoantennae;61
6.1;4.1 Introduction;61
6.1.1;4.1.1 Fractals;63
6.1.1.1;4.1.1.1 Radio Frequency Fractal Antenna;64
6.2;4.2 Fractal Nanostructures;65
6.2.1;4.2.1 Sierpinski Triangle and Carpet;65
6.2.2;4.2.2 Fractal Tree Geometries;69
6.2.2.1;4.2.2.1 Ternary Tree Fractal;69
6.3;4.3 Conclusion;77
6.4;References;80
7;5 Compact Slow-Light Enhaced Plasmonic Waveguide Refractive Index Sensors;83
7.1;5.1 Introduction;84
7.2;5.2 Slow-Light Enhanced Plasmonic Waveguide Refractive Index Sensors;85
7.2.1;5.2.1 MDM Waveguide with Small Width System;86
7.2.2;5.2.2 MDM Side-Coupled to Arrays of Stub Resonators System;89
7.2.3;5.2.3 MDM Side-Coupled to Arrays of Double-Stub Resonators System;96
7.3;5.3 Mach-Zehnder Interferometer Based Slow-Light Enhanced Plasmonic Waveguide Sensors;100
7.3.1;5.3.1 Conventional MDM Waveguide in the Sensing Arm;102
7.3.2;5.3.2 MDM Side-Coupled to Arrays of Double-Stub Resonators System in the Sensing Arm;104
7.4;References;112
8;6 Fabrication, Properties and Applications of Plasmene Nanosheet;115
8.1;6.1 Introduction;116
8.2;6.2 Synthesis of Constituent Plasmonic Elements;117
8.2.1;6.2.1 Synthesis of Spherical Plasmonic Nanoparticles;117
8.2.2;6.2.2 Synthesis of Anisotropic Plasmonic Nanoparticles;118
8.2.2.1;6.2.2.1 Gold Nanorods;119
8.2.2.2;6.2.2.2 Gold Nanobipyramids;120
8.2.2.3;6.2.2.3 Gold Rhombic Dodecahedral;120
8.2.2.4;6.2.2.4 Gold Nanostars;121
8.2.2.5;6.2.2.5 Core-Shell Au@Ag Nanocubes/Nanobricks;121
8.3;6.3 Fabrication of Plasmonic Nanosheet;121
8.3.1;6.3.1 Programmable Self-Assembly;122
8.3.2;6.3.2 Microhole-Confined Self-Assembly;122
8.3.3;6.3.3 Liquid-Liquid Interfacial Assembly;124
8.3.4;6.3.4 Air-Water Interfacial Self-Assembly;126
8.3.4.1;6.3.4.1 General Approach for Plasmene Nanosheets;126
8.3.4.2;6.3.4.2 Orientational Control of Nanoparticle Self- Assembly;127
8.4;6.4 Patterning of 2D Nanosheet into 1D Nanoribbon and 3D Origami;129
8.5;6.5 Properties of Plasmonic Nanosheets;130
8.5.1;6.5.1 Gap Plasmon Mode;130
8.5.1.1;6.5.1.1 Particle Shape and Size Effect;130
8.5.1.2;6.5.1.2 External Strain Effect;131
8.5.2;6.5.2 Propagating Plasmon Mode;132
8.5.3;6.5.3 Mechanical Properties;133
8.5.4;6.5.4 Asymmetric Ionic Transport Behaviour;133
8.6;6.6 Application of Plasmonic Nanosheets;134
8.6.1;6.6.1 Plasmene Based Membrane Resonator;134
8.6.2;6.6.2 Plasmene Nanosheet as Next Generation SERS Substrate;134
8.6.3;6.6.3 Quantitative Drug Identification Using Plasmene Nanosheet;135
8.6.4;6.6.4 Plasmene Based Anti-counterfeit Security Label;136
8.7;6.7 Conclusion;137
8.8;References;137
9;7 Experimental Observation of Melting of the Effective Minkowski Spacetime in Cobalt-Based Ferrofluids;143
9.1;7.1 Introduction;144
9.2;7.2 Electromagnetic Properties of Cobalt Nanoparticle-Based Ferrofluid;146
9.3;7.3 Analogue Gravity in Ferrofluids;148
9.4;7.4 Microscopic Investigation of Minkowski Spacetime Melting;153
9.5;7.5 Final Remarks;163
9.6;References;163
10;8 Surface Plasmon Resonance Based Fiber Optic Sensors Utilizing Zinc Oxide Thin Films and Nanostructures;165
10.1;8.1 Introduction;166
10.2;8.2 SPR Based Sensors and Performance Parameters;167
10.3;8.3 Zinc Oxide: Background;170
10.3.1;8.3.1 ZnO as High Index Layer;171
10.3.2;8.3.2 ZnO as Sensing Material;171
10.4;8.4 Electric Field Intensity at Interfaces;171
10.5;8.5 SPR Spectrum;173
10.6;8.6 Dispersion Relations;175
10.6.1;8.6.1 Homogeneous Film;175
10.6.2;8.6.2 Nanocomposite Film;176
10.6.3;8.6.3 Experimental Methods of Coating;176
10.7;8.7 Zinc Oxide as Over Layer;177
10.8;8.8 Hazardous and Pollutant Gases;181
10.8.1;8.8.1 Hydrogen Sulphide (H2S) Gas Sensor;182
10.8.2;8.8.2 Hydrogen (H2) Gas Sensor;184
10.9;8.9 Water Impurities Sensors;190
10.10;8.10 Phenyl Hydrazine Sensor;194
10.11;8.11 Summary;200
10.12;References;201
11;9 Frontiers of Light Dynamics in Photonic Crystals;204
11.1;9.1 Introduction;204
11.2;9.2 Planar Photonic Crystals;205
11.3;9.3 Photonic Crystal Fibers;207
11.4;9.4 Surface Plasmon Resonance;209
11.5;9.5 Negative Index Materials;210
11.6;9.6 Conclusion;212
11.7;References;213
12;10 LSPR Biosensing: Recent Advances and Approaches;216
12.1;10.1 Introduction;216
12.2;10.2 Advantage Over Other Planar Techniques;217
12.3;10.3 Theoretical Concepts;218
12.3.1;10.3.1 Mie Theory;219
12.3.2;10.3.2 Factors Affecting LSPR Peak Frequency;219
12.4;10.4 Biomolecular Biosensing and Nanoplasmonics;220
12.4.1;10.4.1 Nanoplasmonics and LSPR;221
12.4.1.1;10.4.1.1 Nanoparticles;221
12.4.1.2;10.4.1.2 Multiplexed Single Nanoparticle LSPR Sensing;221
12.4.1.3;10.4.1.3 Nickel Nanoparticles (NiNPs);222
12.4.1.4;10.4.1.4 Platinum Nanoparticles (PtNPs);222
12.4.1.5;10.4.1.5 Silver and Gold Nanoparticles (AgNPs/AuNPs);223
12.4.2;10.4.2 Nanotubes (NTs) – Nanoparticle (NPs) Hybrids;224
12.4.2.1;10.4.2.1 Single-Wall Carbon Nanotubes (SWCNTs);225
12.4.2.2;10.4.2.2 Multi Wall Carbon Nanotubes (MWCNT);225
12.4.3;10.4.3 Gold Nanorod (GNR);225
12.4.3.1;10.4.3.1 Potential-Scanning LSPR Sensors;226
12.4.4;10.4.4 Nanowell;227
12.4.5;10.4.5 Platinum Nanorings;227
12.4.6;10.4.6 Gold Nanoantennas;227
12.4.7;10.4.7 LSPR in Gold (Au) Clusters;228
12.5;10.5 Localized and Propagating SPR;228
12.6;10.6 LSPR Imaging;228
12.7;10.7 LSPR Biosensing in Point-of-Care Diagnostic Devices;230
12.7.1;10.7.1 LSPR Gold Nanobiosensor for Immunoassay;231
12.8;10.8 LSPR for Biomolecular Assays;232
12.8.1;10.8.1 Poly(methyl methacrylate) Polymer Based LSPR Biosensor Chips;232
12.8.2;10.8.2 LSPR Enhanced Visible-Light Photoelectrochemical Biosensors;232
12.8.3;10.8.3 Electrofocusing-enhanced Localized Surface Plasmon Resonance Biosensors;233
12.8.4;10.8.4 High-sensitivity Detection of ATP Using a Localized Surface Plasmon Resonance (LSPR) Sensor and Split Aptamers;233
12.9;10.9 LSPR Biosensing: Challenges and Solutions;234
12.9.1;10.9.1 Improving Limit of Detection;234
12.9.1.1;10.9.1.1 Improving Limit of Detection: Enzymatic Amplification;234
12.9.1.2;10.9.1.2 Improving Limit of Detection: Plasmonic Coupling of NPs;234
12.9.1.3;10.9.1.3 Improving Limit of Detection: Biomolecular Conformationally-Gated Amplification;235
12.9.2;10.9.2 Selectivity Improvisation in Complex Biological Solution;235
12.9.2.1;10.9.2.1 Selectivity Improvisation: Functionalization Layers;236
12.9.2.2;10.9.2.2 Selectivity Improvisation: Biological Scaffolds;236
12.9.2.3;10.9.2.3 Plasmon Ruler;236
12.9.2.4;10.9.2.4 Selectivity Improvisation: Size-Selective Films or Shape Complementarity;237
12.9.3;10.9.3 LSPR Biosensing for Membrane-Associated Species;237
12.9.3.1;10.9.3.1 LSPR Biosensors Utilizing Supported Lipid Bilayers;237
12.10;10.10 Conclusion;237
12.11;References;238
13;Index;244
