| Foreword |
| Preface |
| Propagating Surface Plasmon Polaritons / Atef Shalabney1: |
| Introduction / 1.1: |
| Surface Plasmons on Smooth Surfaces / 1.2: |
| Surface Plasmon at Single Interface / 1.2.1: |
| Surface Plasmon in Multilayer Systems / 1.2.2: |
| Electromagnetic Energy Confinement and Field Enhancement / 1.2.3: |
| Excitation of Surface Plasmon Polaritons / 1.2.4: |
| Applications / 1.3: |
| Surface Plasmon Resonance-Based Sensors / 1.3.1: |
| Enhanced Spectroscopy and Emissive Processes / 1.3.2: |
| Concluding Remarks / 1.4: |
| Different Strategies for Glycan Immobilization onto Plasmonic Interfaces / Sabine Szunerits ; Rabah Boukherroub2: |
| Carboxymethylated Dextran Layers: The BiAcore Chip / 2.1: |
| Self-Assembled Monolayers Based on Thiolated Functional Groups / 2.3: |
| Polymer Films / 2.4: |
| Lamellar SPR Structures / 2.5: |
| Conclusion |
| Biophysics of DNA: DNA Melting Curve Analysis with Surface Plasmon Resonance Imaging / Arnaud Buhot ; Julia Pingel ; Jean-Bernard Fiche ; Roberto Calemczuk ; Thierry Livache3: |
| Temperature Regulation of SPRi for DNA Melting Curves Analysis / 3.1: |
| SPRi Apparatus with Temperature Regulation / 3.2.1: |
| Equilibrium versus Out-of-Equilibrium Melting Curves / 3.2.2: |
| Stability of Grafting Chemistries at High Temperatures / 3.2.3: |
| Electro-copolymerization of poly-pyrrole / 3.2.3.1: |
| Thiol self-assembling monolayer / 3.2.3.2: |
| Physico-Chemistry of DNA Melting at a Surface / 3.3: |
| Effects of Denaturant Molecules / 3.3.1: |
| Effects of Salt Concentration / 3.3.2: |
| Detection of Single Point Mutation from Melting Curve Analysis / 3.4: |
| Detection with Oligonucleotides Targets / 3.4.1: |
| Detection Limit of Somatic Mutations / 3.4.2: |
| Homozygous and Heterozygous Detection of PCR Products / 3.4.3: |
| Plasmon Waveguide Resonance Spectroscopy: Principles and Applications in Studies of Molecular Interactions within Membranes / Isabel D. Alves3.5: |
| Plasmon Spectroscopy / 4.1: |
| Description of Surface Plasmons / 4.2.1: |
| Types of Surface Plasmon Resonances / 4.2.2: |
| Conventional surface plasmon resonance / 4.2.2.1: |
| Plasmon-waveguide resonance / 4.2.2.2: |
| PWR Spectral Analysis / 4.2.3: |
| PWR Applications / 4.3: |
| Lipid Bilayers / 4.3.1: |
| Solid-supported lipid bilayers / 4.3.1.1: |
| Membranes composed of cellular membrane fragments / 4.3.1.2: |
| GPCR Insertion into Membranes, Activation and Signaling / 4.3.2: |
| Role of Lipids in GPCR Activation, Signaling, and Partition into Membrane Microdomains / 4.3.3: |
| Interaction of Membrane Active Peptides with Lipid Membranes / 4.3.4: |
| PWR Ongoing Developments / 4.4: |
| Surface-Wave Enhanced Biosensing / Wolfgang Knoll ; Amal Kasry ; Chun-Jen Huang ; Yi Wang ; Jakub Dostalek5: |
| Surface Plasmon Field-Enhanced Fluorescence Detection / 5.1: |
| Long-Range Surface Plasmon Fluorescence Spectroscopy / 5.3: |
| Optical Waveguide Fluorescence Spectroscopy / 5.4: |
| Conclusions / 5.5: |
| Infrared Surface Plasmon Resonance / Stefan Franzen ; Mark Losego ; Misun Kang ; Edward Sachet ; Jon-Paul Maria6: |
| The Hypothesis That Surface Plasmon Resonance Will Be Observed in Free Electron Conductors / 6.1: |
| Confirmation of the Hypothesis That Conducting Metal Oxides Can Support Surface Plasmon Resonance / 6.3: |
| The Effect of Carrier Concentration / 6.4: |
| The Effect of Mobility / 6.5: |
| Hybrid Plasmons: Understanding the Relationship between Localized LSPR and SPR / 6.6: |
| The Effect of Materials Properties on the Observed Surface Plasmon Polaritons / 6.7: |
| Detection of Mid-Infrared Surface Plasmon Polaritons / 6.8: |
| The Search for High Mobility Conducting Metal Oxides / 6.9: |
| The Unique Characteristics of Localized Surface Plasmon Resonance / Gaetan Leveque ; Abdellatif Akjouj6.10: |
| Localized Surface Plasmon Resonance of a Single Particle / 7.1: |
| Single Particle in the Quasi-Static Approximation / 7.1.1: |
| Case of the spherical particle / 7.1.1.1: |
| Case of the spheroidal particle / 7.1.1.2: |
| Beyond the Quasi-Static Approximation / 7.1.2: |
| Examples of Coupled Plasmonic Systems / 7.2: |
| Chain of Identical Particles / 7.2.1: |
| Chain of Different Particles / 7.2.2: |
| Localized Surface Plasmon for a Periodic Nano structure / 7.3: |
| Model and Simulation Method / 7.3.1: |
| Absorption Spectra for Au Nano structures Array / 7.3.2: |
| Influence of the Thickness of a Diamond Dielectric Overlayer on the LSPR / 7.3.3: |
| Advances in the Fabrication of Plasmonic Nanostructures: Plasmonics Going Down to the IManoscale / Thomas Maurer7.3.4: |
| Top-Down Techniques: A Mask-Based Process / 8.1: |
| Conventional Lithography Techniques: Photolithography and Particle Beam Lithography / 8.2.1: |
| Photolithography / 8.2.1.1: |
| Particle beam lithography / 8.2.1.2: |
| Advanced Lithography Techniques: Masks Coming from Researcher Imagination / 8.2.2: |
| Multilevel laser interference lithography / 8.2.2.1: |
| Nanostencil lithography / 8.2.2.2: |
| Self-assembly techniques for mask fabrication: nanosphere lithorgaphy and block copolymer lithography / 8.2.2.3: |
| Direct Writing / 8.2.3: |
| Particle beam-induced etching and particle beam-induced deposition / 8.2.3.1: |
| Laser ablation / 8.2.3.2: |
| 3D laser lithography / 8.2.3.3: |
| Printing, Replica Molding and Embossing / 8.2.4: |
| Printing / 8.2.4.1: |
| Replica molding / 8.2.4.2: |
| Embossing / 8.2.4.3: |
| Conclusion about the Top-Down Strategy / 8.2.5: |
| Bottom-Up Techniques: Atom by Atom Building / 8.3: |
| The Bottom-Up Strategy / 8.3.1: |
| Physical route / 8.3.1.1: |
| Electrochemical route / 8.3.1.2: |
| Chemical route / 8.3.1.3: |
| Self-Organization, the Next Challenge of Plasmonics / 8.3.2: |
| Laboratory self-assembly techniques / 8.3.2.1: |
| Mass Production Using Wet Coating Processes / 8.3.3: |
| Mixing Top-Down and Bottom-Up Routes / 8.4: |
| Porous Membranes for Ordered Nanowires Growth / 8.4.1: |
| Copolymer Template Control of Plasmonic Nanoparticle Synthesis via Thermal Annealing / 8.4.2: |
| Let's Play Your Imagination / 8.4.3: |
| Conclusion: First, Choose Materials / 8.5: |
| Colorimetric Sensing Based on Metallic Nanostructures / Daniel Aili ; Borja Sepulveda9: |
| Introduction and Historical Perspective / 9.1: |
| Synthesis of Gold Nanoparticles / 9.2: |
| Optical Properties of Gold Nanoparticles / 9.3: |
| Colloidal Stability and Surface Chemistry of Gold Nanoparticles / 9.4: |
| Surface Functionalization / 9.4.1: |
| Molecular Recognition for Modulation of Nanoparticle Stability / 9.5: |
| Cross-Linking Assays / 9.5.1: |
| Redispersion Assays / 9.5.2: |
| Non-Cross-Linking Assays / 9.5.3: |
| Outlook and Challenges / 9.6: |
| Assays with Reversed Sensitivity and Plasmonic ELISA / 9.6.1: |
| Assays for the Future / 9.6.2: |
| Surface-Enhanced Raman Scattering: Principles and Applications for Single-Molecule Detection / Diego P. dos Santos ; Marcia I. A. Temperini ; Alexandre G. Brolo10: |
| Raman Scattering / 10.1: |
| SERS / 10.3: |
| SERS Substrates / 10.4: |
| Single-Molecule SERS / 10.5: |
| Graphene-Based Plasmonics / Sinan Balci ; Emre Ozan Polat ; Coskun Kocabas10.6: |
| Introduction: Plasmons in Reduced Dimensions / 11.1: |
| Optical Properties of Graphene / 11.2: |
| Synthesis of Graphene / 11.3: |
| Plasma Oscillations on Graphene-Metal Surface / 11.4: |
| Graphene Functionalized SPR Sensors / 11.5: |
| Graphene Passivation for SPR Sensors / 11.6: |
| Biomolecular Detection Using Graphene Functionalized SPR Sensors / 11.7: |
| Graphene Oxide Functionalization / 11.8: |
| Gate-Tunable Graphene Plasmonics / 11.9: |
| SPR: An Industrial Point of View / Iban Larroulet11.10: |
| Companies / 12.1: |
| Future Trends / 12.3: |
| Index |
| Foreword |
| Preface |
| Propagating Surface Plasmon Polaritons / Atef Shalabney1: |
| Introduction / 1.1: |
| Surface Plasmons on Smooth Surfaces / 1.2: |
| Surface Plasmon at Single Interface / 1.2.1: |
