Plasmonic Resonators
portes grátis
Plasmonic Resonators
Fundamentals, Advances, and Applications
Iwanaga, Masanobu
Pan Stanford Publishing Pte Ltd
09/2016
324
Dura
Inglês
9789814745062
15 a 20 dias
598
Descrição não disponível.
Introduction. Plasma frequency. Optical constants in metals. Metal-Insulator Interface where SPPs emerge. Brief overview of the history. Numerical methods. Nanofabrication methods. Chapter summary. Response Function Theory. Classical model for response function. Quantum mechanical description for response function. Spectral theory. Generalized theory for response function. Chapter summary. Plasmonic Resonators. Plasmonic waveguides. Nanoparticle plasmonic resonators. Nanoparticle-assembled plasmonic resonators. Single-layer lattices. Collective oscillation associated with longitudinal component in plasmonic resonators. Plasmonic resonators of simply stacked structures. Plasmonic resonators with chirality. Plasmonic resonators of stacked complementary (SC) structures. Perfect absorbers. Chapter summary. Nonlocality on Plasmonic Resonances. Nonlocal responses in far-field spectra. Nonlocal responses in near-field scattering. Optical nonlocality in plasmonic resonators. Chapter summary. Plasmonic Enhancement. Principles of Plas*. Purcell effect. PlasPL. Surface-plasmon-amplified stimulated emission resonators (SPASER). Strong coupling of plasmons with excitons and other resonances. PlasRaman. PlasCat. PlasNLO. Other Plas*. IR emitters. Chapter summary. Future Prospects. Status after two decades since the era of nanotechnology. Directions being opened. Challenges in near future. Concluding remarks.
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Top View SEM Image;resonance;SEM Image;nonlocal;Gap Plasmons;response;Plasmonic Waveguide;relative;Dispersion Diagram;permittivity;IR Emitter;dispersion;Nonlocal Responses;diagrams;Au NPs;dielectric;Local Plasmon;function;Ultrafast Response;fano;Resonant Energy;Xy Section;Negative Refractive Index;FDTD Method;Ag Single Crystal;Plasma Frequency ?p;Waveguide Modes;Babinet's Principle;Spp Dispersion;Hy Components;SOI Substrate;Te Polarization;Air Holes;Au Nanorod;Ez Component
Introduction. Plasma frequency. Optical constants in metals. Metal-Insulator Interface where SPPs emerge. Brief overview of the history. Numerical methods. Nanofabrication methods. Chapter summary. Response Function Theory. Classical model for response function. Quantum mechanical description for response function. Spectral theory. Generalized theory for response function. Chapter summary. Plasmonic Resonators. Plasmonic waveguides. Nanoparticle plasmonic resonators. Nanoparticle-assembled plasmonic resonators. Single-layer lattices. Collective oscillation associated with longitudinal component in plasmonic resonators. Plasmonic resonators of simply stacked structures. Plasmonic resonators with chirality. Plasmonic resonators of stacked complementary (SC) structures. Perfect absorbers. Chapter summary. Nonlocality on Plasmonic Resonances. Nonlocal responses in far-field spectra. Nonlocal responses in near-field scattering. Optical nonlocality in plasmonic resonators. Chapter summary. Plasmonic Enhancement. Principles of Plas*. Purcell effect. PlasPL. Surface-plasmon-amplified stimulated emission resonators (SPASER). Strong coupling of plasmons with excitons and other resonances. PlasRaman. PlasCat. PlasNLO. Other Plas*. IR emitters. Chapter summary. Future Prospects. Status after two decades since the era of nanotechnology. Directions being opened. Challenges in near future. Concluding remarks.
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Top View SEM Image;resonance;SEM Image;nonlocal;Gap Plasmons;response;Plasmonic Waveguide;relative;Dispersion Diagram;permittivity;IR Emitter;dispersion;Nonlocal Responses;diagrams;Au NPs;dielectric;Local Plasmon;function;Ultrafast Response;fano;Resonant Energy;Xy Section;Negative Refractive Index;FDTD Method;Ag Single Crystal;Plasma Frequency ?p;Waveguide Modes;Babinet's Principle;Spp Dispersion;Hy Components;SOI Substrate;Te Polarization;Air Holes;Au Nanorod;Ez Component
