Nanoantennas and Plasmonics: Modelling, Design and Fabrication
Herausgeber: Werner, Douglas H.; Kang, Lei; Campbell, Sawyer D.
Nanoantennas and Plasmonics: Modelling, Design and Fabrication
Herausgeber: Werner, Douglas H.; Kang, Lei; Campbell, Sawyer D.
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This book presents cutting-edge research advances in the rapidly growing areas of nanoantennas and plasmonics as well as their related enabling technologies and applications.
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This book presents cutting-edge research advances in the rapidly growing areas of nanoantennas and plasmonics as well as their related enabling technologies and applications.
Produktdetails
- Produktdetails
- Electromagnetic Waves
- Verlag: Institution of Engineering & Technology
- Seitenzahl: 472
- Erscheinungstermin: 12. November 2020
- Englisch
- Abmessung: 239mm x 163mm x 28mm
- Gewicht: 907g
- ISBN-13: 9781785618376
- ISBN-10: 1785618377
- Artikelnr.: 57694886
- Electromagnetic Waves
- Verlag: Institution of Engineering & Technology
- Seitenzahl: 472
- Erscheinungstermin: 12. November 2020
- Englisch
- Abmessung: 239mm x 163mm x 28mm
- Gewicht: 907g
- ISBN-13: 9781785618376
- ISBN-10: 1785618377
- Artikelnr.: 57694886
* Chapter 1: Optical properties of plasmonic nanoloop antennas
* Chapter 2: Passive and active nano cylinders for enhanced and
directive radiation and scattering phenomena
* Chapter 3: Coherent control of light scattering
* Chapter 4: Time domain modeling with the generalized dispersive
material model
* Chapter 5: Inverse-design of plasmonic and dielectric optical
nanoantennas
* Chapter 6: Multi-level carrier kinetics models for computational
nanophotonics
* Chapter 7: Nonlinear multipolar interference: from nonreciprocal
directionality to one-way nonlinear mirror
* Chapter 8: Plasmonic metasurfaces for controlling harmonic
generations
* Chapter 9: Optical nanoantennas for enhanced THz emission
* Chapter 10: Active photonics based on phase-change materials and
reconfigurable nanowire systems
* Chapter 11: Dancing angels on the point of a needle: nanofabrication
for subwavelength optics
* Chapter 2: Passive and active nano cylinders for enhanced and
directive radiation and scattering phenomena
* Chapter 3: Coherent control of light scattering
* Chapter 4: Time domain modeling with the generalized dispersive
material model
* Chapter 5: Inverse-design of plasmonic and dielectric optical
nanoantennas
* Chapter 6: Multi-level carrier kinetics models for computational
nanophotonics
* Chapter 7: Nonlinear multipolar interference: from nonreciprocal
directionality to one-way nonlinear mirror
* Chapter 8: Plasmonic metasurfaces for controlling harmonic
generations
* Chapter 9: Optical nanoantennas for enhanced THz emission
* Chapter 10: Active photonics based on phase-change materials and
reconfigurable nanowire systems
* Chapter 11: Dancing angels on the point of a needle: nanofabrication
for subwavelength optics
* Chapter 1: Optical properties of plasmonic nanoloop antennas
* Chapter 2: Passive and active nano cylinders for enhanced and
directive radiation and scattering phenomena
* Chapter 3: Coherent control of light scattering
* Chapter 4: Time domain modeling with the generalized dispersive
material model
* Chapter 5: Inverse-design of plasmonic and dielectric optical
nanoantennas
* Chapter 6: Multi-level carrier kinetics models for computational
nanophotonics
* Chapter 7: Nonlinear multipolar interference: from nonreciprocal
directionality to one-way nonlinear mirror
* Chapter 8: Plasmonic metasurfaces for controlling harmonic
generations
* Chapter 9: Optical nanoantennas for enhanced THz emission
* Chapter 10: Active photonics based on phase-change materials and
reconfigurable nanowire systems
* Chapter 11: Dancing angels on the point of a needle: nanofabrication
for subwavelength optics
* Chapter 2: Passive and active nano cylinders for enhanced and
directive radiation and scattering phenomena
* Chapter 3: Coherent control of light scattering
* Chapter 4: Time domain modeling with the generalized dispersive
material model
* Chapter 5: Inverse-design of plasmonic and dielectric optical
nanoantennas
* Chapter 6: Multi-level carrier kinetics models for computational
nanophotonics
* Chapter 7: Nonlinear multipolar interference: from nonreciprocal
directionality to one-way nonlinear mirror
* Chapter 8: Plasmonic metasurfaces for controlling harmonic
generations
* Chapter 9: Optical nanoantennas for enhanced THz emission
* Chapter 10: Active photonics based on phase-change materials and
reconfigurable nanowire systems
* Chapter 11: Dancing angels on the point of a needle: nanofabrication
for subwavelength optics