Evanescent Waves in Optics
-15%
portes grátis
Evanescent Waves in Optics
An Introduction to Plasmonics
Guzman, Angela; Sibilia, Concita; Bertolotti, Mario
Springer International Publishing AG
11/2017
259
Dura
Inglês
9783319612607
15 a 20 dias
Descrição não disponível.
PRELIMINARY TABLE OF CONTENTS Preface Chapter I Basic electromagnetics 1.1 Introduction 1.2 Maxwell's equations 1.3 Waves 1.4 Phase velocity 1.5 Dispersion 1.6 Pulses and Group velocity 1.7 Polarization 1.8 Jones matrices, Stokes parameters and the Poincare sphere 1.9 Optically anisotropic media 1.9.1 Uniaxial crystals 1.9.2 Biaxial crystals 1.10 Chirality 1.11 Gaussian beams Chapter II Evanescent Waves 2.1 Introduction 2.2 Reflection and refraction 2.2.1 The reflection and refraction Cartesio-Snell law 2.2.2 Extension to surfaces with a phase gradient 2.2.3 Fresnel coefficients 2.2.3.1 Reflection and refraction for n1 2.2.3.2 The case n1>n2 2.3 Evanescent waves 2.4 Energy transport of evanescent waves 2.5 Tunnelling effect 2.6 Reflection and refraction in the presence of absorption 2.7 Reflection and refraction with materials with negative refractive index 2.8 X-Ray Evanescent Waves 2.9 Reflection and refraction of plane waves at a boundary between an isotropic and a birefringent medium 2.10 The plane wave decomposition of the field 2.11 The Classical Limit of Resolution Explained 2.12 Reflection and refraction of Gaussian beams 2.13 Evanescent waves in diffraction Chapter III Evanescent Waves in Waveguides 3.1 Introduction 3.2 Plane waveguides 3.2.1 TE Modes 3.2.2 TM Modes 3.2.3 The radiation and substrate modes 3.3 Coupling of light to a plane waveguide 3.4 Coupling of two waveguides 3.5 Optical fibres 3.6 Multilayers and PBG 3.6.1 Infinite periodic structures 3.6.2 Finite 1D PBG 3.7 The role of evanescent waves in waveguide sensors Chapter IV High resolution optical microscopes (in which evanescent waves play a role) 4.1 Introduction 4.2 Scanning Near-field Optical Microscope (SNOM) 4.3 Scanning Tunneling Optical Microscope (STOM) 4.4 Total Internal Reflection Fluorescence (TIRF) Chapter V Plasmons 5.1 Introduction 5.2 Plasmon solutions 5.3 Bulk Plasmons 5.4 Surface Plasmon Polaritons (SPPs) 5.5 Properties of plasmons 5.6 Excitation and coupling of plasmons 5.7 Multilayer systems 5.8 Localised Surface Plasmons 5.9 Surface Phonon Polaritons in Dielectric and Semiconductors 5.10 The plasmons in optical nonlinear materials 5.11 Other surface waves 5.11.1 Dyakonov waves 5.11.2 Surface waves in negative index materials 5.11.3 Tamm plasmon polaritons Chapter VI Applications of plasmons 6.1 Introduction 6.2 Surface Enhanced Raman Scattering (SERS) 6.3 Surface Plasmon sensors 6.4 Extraordinary optical transmission through arrays of sub-wavelength holes 6.5 Surface Plasmon circuitry 6.6 Plasmon lasers and SPASER 6.6.1 SPASER 6.7 Plasmons for solar cells 6.8 Plasmon microscopy 6.9 Blackbody spatial and temporal coherence 6.10 Controlled thermal emission using plasma resonances Chapter VII Quantization of evanescent waves, surface plasmons and surface plasmon polaritons 7.1 Introduction 7.2 Quantization of evanescent waves 7.3 Amplification of evanescent waves by a negative index slab 7.4 Absorption and emission of evanescent photons 7.5 Evanescent field and surface plasmon excitation 7.6 Quantization of the surface plasmon field 7.7 Quantum-mechanical description of the excitation of surface plasmon polaritons on metal surfaces by single photons. 7.8 Quantization of surface plasmon polaritons: the Bogoliubov transformations 7.9 Single photon nonlinear optics with plasmons 7.10 Surface Plasmon Polaritons and Quantum Information
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PRELIMINARY TABLE OF CONTENTS Preface Chapter I Basic electromagnetics 1.1 Introduction 1.2 Maxwell's equations 1.3 Waves 1.4 Phase velocity 1.5 Dispersion 1.6 Pulses and Group velocity 1.7 Polarization 1.8 Jones matrices, Stokes parameters and the Poincare sphere 1.9 Optically anisotropic media 1.9.1 Uniaxial crystals 1.9.2 Biaxial crystals 1.10 Chirality 1.11 Gaussian beams Chapter II Evanescent Waves 2.1 Introduction 2.2 Reflection and refraction 2.2.1 The reflection and refraction Cartesio-Snell law 2.2.2 Extension to surfaces with a phase gradient 2.2.3 Fresnel coefficients 2.2.3.1 Reflection and refraction for n1 2.2.3.2 The case n1>n2 2.3 Evanescent waves 2.4 Energy transport of evanescent waves 2.5 Tunnelling effect 2.6 Reflection and refraction in the presence of absorption 2.7 Reflection and refraction with materials with negative refractive index 2.8 X-Ray Evanescent Waves 2.9 Reflection and refraction of plane waves at a boundary between an isotropic and a birefringent medium 2.10 The plane wave decomposition of the field 2.11 The Classical Limit of Resolution Explained 2.12 Reflection and refraction of Gaussian beams 2.13 Evanescent waves in diffraction Chapter III Evanescent Waves in Waveguides 3.1 Introduction 3.2 Plane waveguides 3.2.1 TE Modes 3.2.2 TM Modes 3.2.3 The radiation and substrate modes 3.3 Coupling of light to a plane waveguide 3.4 Coupling of two waveguides 3.5 Optical fibres 3.6 Multilayers and PBG 3.6.1 Infinite periodic structures 3.6.2 Finite 1D PBG 3.7 The role of evanescent waves in waveguide sensors Chapter IV High resolution optical microscopes (in which evanescent waves play a role) 4.1 Introduction 4.2 Scanning Near-field Optical Microscope (SNOM) 4.3 Scanning Tunneling Optical Microscope (STOM) 4.4 Total Internal Reflection Fluorescence (TIRF) Chapter V Plasmons 5.1 Introduction 5.2 Plasmon solutions 5.3 Bulk Plasmons 5.4 Surface Plasmon Polaritons (SPPs) 5.5 Properties of plasmons 5.6 Excitation and coupling of plasmons 5.7 Multilayer systems 5.8 Localised Surface Plasmons 5.9 Surface Phonon Polaritons in Dielectric and Semiconductors 5.10 The plasmons in optical nonlinear materials 5.11 Other surface waves 5.11.1 Dyakonov waves 5.11.2 Surface waves in negative index materials 5.11.3 Tamm plasmon polaritons Chapter VI Applications of plasmons 6.1 Introduction 6.2 Surface Enhanced Raman Scattering (SERS) 6.3 Surface Plasmon sensors 6.4 Extraordinary optical transmission through arrays of sub-wavelength holes 6.5 Surface Plasmon circuitry 6.6 Plasmon lasers and SPASER 6.6.1 SPASER 6.7 Plasmons for solar cells 6.8 Plasmon microscopy 6.9 Blackbody spatial and temporal coherence 6.10 Controlled thermal emission using plasma resonances Chapter VII Quantization of evanescent waves, surface plasmons and surface plasmon polaritons 7.1 Introduction 7.2 Quantization of evanescent waves 7.3 Amplification of evanescent waves by a negative index slab 7.4 Absorption and emission of evanescent photons 7.5 Evanescent field and surface plasmon excitation 7.6 Quantization of the surface plasmon field 7.7 Quantum-mechanical description of the excitation of surface plasmon polaritons on metal surfaces by single photons. 7.8 Quantization of surface plasmon polaritons: the Bogoliubov transformations 7.9 Single photon nonlinear optics with plasmons 7.10 Surface Plasmon Polaritons and Quantum Information
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