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Plasmonic Nanoelectronics and Sensing [electronic resource] / Er-Ping Li and Hong-Son Chu.

By: Contributor(s): Material type: TextTextSeries: EuMA high frequency technologies seriesPublication details: Cambridge : Cambridge University Press, 2014.Description: 1 online resource (266 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781107731875 (electronic bk.)
  • 1107731879 (electronic bk.)
  • 9781107723740 (electronic bk.)
  • 1107723744 (electronic bk.)
Subject(s): Genre/Form: Additional physical formats: Print version:: Plasmonic Nanoelectronics and Sensing.DDC classification:
  • 620/.5 23
LOC classification:
  • T174.7
Online resources:
Contents:
Cover; Half title; Series; Title; Copyright; Contents; Contributors; Preface; 1 Fundamentals of plasmonics; 1.1 Electromagnetic field equations; 1.1.1 Maxwell's equations in a medium; 1.1.2 Material equations; 1.1.3 Temporal and spatial dispersion in metals; 1.2 The local-response approximation; 1.2.1 The energy of an electromagnetic field in metals; 1.2.2 Properties of the complex dielectric permittivity; 1.2.3 The conduction-electron contribution; 1.2.4 The bound-charge contribution; 1.3 Electromagnetic fields in metals; 1.3.1 Plasmon classification; 1.3.2 Bulk plasmon modes.
1.3.3 Surface plasmon modesReferences; 2 Plasmonic properties of metal nanostructures; 2.1 Plasmonic modes in spherical geometry; 2.1.1 Spherical harmonics; 2.1.2 Electromagnetic fields in vector spherical harmonics; 2.1.3 Spherical plasmons; 2.1.4 Scattering by a sphere; 2.1.5 Cross-sections; 2.1.6 A multilayer sphere; 2.2 Plasmonic modes in cylindrical geometry; 2.2.1 Cylindrical harmonics; 2.2.2 Electromagnetic fields in vector cylindrical harmonics; 2.2.3 Cylindrical plasmon polaritons; 2.2.4 Scattering by a cylinder; 2.2.5 Cross-sections per unit length; 2.2.6 Multilayer cylinder.
2.3 Plasmonic modes in planar geometry2.3.1 Planar harmonics; 2.3.2 Electromagnetic fields in vector planar harmonics; 2.3.3 Planar plasmon polaritons; 2.3.4 Reflection and transmission by a slab; 2.3.5 Reflectance, transmittance, and absorptance; 2.3.6 A multilayer slab; References; 3 Frequency-domain methods for modeling plasmonics; 3.1 Introduction; 3.2 Rigorous coupled-wave analysis; 3.2.1 Formulations; 3.2.2 Modeling 2D and 3D plasmonic nanostructures with RCWA; 3.3 A semi-analytical method for near-field coupling study; 3.3.1 Superlens and subwavelength imaging.
3.3.2 Object-superlens coupling3.4 Summary; References; 4 Time-domain simulation for plasmonic devices; 4.1 Introduction; 4.2 Formulation; 4.2.1 A model for metals; 4.2.2 A model for solid-state materials; 4.2.3 Simulation of an MSM waveguide and a microcavity; 4.2.4 SPP generation using an MSM microdisk; 4.3 Surface plasmon generation in semiconductor devices; 4.4 Implementation of the LD model on a GPU; 4.4.1 GPU implementation; 4.4.2 Applications; 4.5 Summary; References; 5 Passive plasmonic waveguide-based devices; 5.1 Introduction.
5.2 The vertical hybrid Ag-SiO[sub(2)]-Si plasmonic waveguide and devices based on it5.2.1 Theoretical background; 5.2.2 The dependence of the propagation characteristics on the thicknessof the SiO[sub(2)] stripe; 5.2.3 The dependence of the propagation characteristics on the dimensionsof the Si nanowire; 5.2.4 The propagation characteristics of the vertical hybrid, metal-insulator-metal, and dielectric-loaded plasmonic waveguides; 5.2.5 Waveguide couplers; 5.2.6 Waveguide bends; 5.2.7 Power splitters; 5.2.8 Ring resonator filters.
Summary: A comprehensive overview, from fundamental theory and numerical methods to the design of real plasmonic structures for nanoelectronic and sensing applications.
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Total holds: 0

Description based on print version record.

Cover; Half title; Series; Title; Copyright; Contents; Contributors; Preface; 1 Fundamentals of plasmonics; 1.1 Electromagnetic field equations; 1.1.1 Maxwell's equations in a medium; 1.1.2 Material equations; 1.1.3 Temporal and spatial dispersion in metals; 1.2 The local-response approximation; 1.2.1 The energy of an electromagnetic field in metals; 1.2.2 Properties of the complex dielectric permittivity; 1.2.3 The conduction-electron contribution; 1.2.4 The bound-charge contribution; 1.3 Electromagnetic fields in metals; 1.3.1 Plasmon classification; 1.3.2 Bulk plasmon modes.

1.3.3 Surface plasmon modesReferences; 2 Plasmonic properties of metal nanostructures; 2.1 Plasmonic modes in spherical geometry; 2.1.1 Spherical harmonics; 2.1.2 Electromagnetic fields in vector spherical harmonics; 2.1.3 Spherical plasmons; 2.1.4 Scattering by a sphere; 2.1.5 Cross-sections; 2.1.6 A multilayer sphere; 2.2 Plasmonic modes in cylindrical geometry; 2.2.1 Cylindrical harmonics; 2.2.2 Electromagnetic fields in vector cylindrical harmonics; 2.2.3 Cylindrical plasmon polaritons; 2.2.4 Scattering by a cylinder; 2.2.5 Cross-sections per unit length; 2.2.6 Multilayer cylinder.

2.3 Plasmonic modes in planar geometry2.3.1 Planar harmonics; 2.3.2 Electromagnetic fields in vector planar harmonics; 2.3.3 Planar plasmon polaritons; 2.3.4 Reflection and transmission by a slab; 2.3.5 Reflectance, transmittance, and absorptance; 2.3.6 A multilayer slab; References; 3 Frequency-domain methods for modeling plasmonics; 3.1 Introduction; 3.2 Rigorous coupled-wave analysis; 3.2.1 Formulations; 3.2.2 Modeling 2D and 3D plasmonic nanostructures with RCWA; 3.3 A semi-analytical method for near-field coupling study; 3.3.1 Superlens and subwavelength imaging.

3.3.2 Object-superlens coupling3.4 Summary; References; 4 Time-domain simulation for plasmonic devices; 4.1 Introduction; 4.2 Formulation; 4.2.1 A model for metals; 4.2.2 A model for solid-state materials; 4.2.3 Simulation of an MSM waveguide and a microcavity; 4.2.4 SPP generation using an MSM microdisk; 4.3 Surface plasmon generation in semiconductor devices; 4.4 Implementation of the LD model on a GPU; 4.4.1 GPU implementation; 4.4.2 Applications; 4.5 Summary; References; 5 Passive plasmonic waveguide-based devices; 5.1 Introduction.

5.2 The vertical hybrid Ag-SiO[sub(2)]-Si plasmonic waveguide and devices based on it5.2.1 Theoretical background; 5.2.2 The dependence of the propagation characteristics on the thicknessof the SiO[sub(2)] stripe; 5.2.3 The dependence of the propagation characteristics on the dimensionsof the Si nanowire; 5.2.4 The propagation characteristics of the vertical hybrid, metal-insulator-metal, and dielectric-loaded plasmonic waveguides; 5.2.5 Waveguide couplers; 5.2.6 Waveguide bends; 5.2.7 Power splitters; 5.2.8 Ring resonator filters.

5.3 Complementary metal-oxide-semiconductor compatible hybrid plasmonic waveguide devices.

A comprehensive overview, from fundamental theory and numerical methods to the design of real plasmonic structures for nanoelectronic and sensing applications.

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