Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes

Optical antennas link objects to light. Here we derive an analytical model for the interaction of dipolar transitions with radiation through nanorod antenna modes, by modeling nanorods as cavities. The model includes radiation damping, accurately describes the complete emission process, and is summa...

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Autores principales: Taminiau, T.H., Stefani, F.D., Van Hulst, N.F.
Formato: JOUR
Materias:
dark modes
electric andmagnetic dipole emitters
metal nanorods
nanoantennas
Optical antennas
subradiance
Nanoantennas
Subradiances
Mathematical models
Nanorods
Optical instruments
Dipole antennas
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_15306984_v11_n3_p1020_Taminiau
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_15306984_v11_n3_p1020_Taminiau
record_format dspace
spelling todo:paper_15306984_v11_n3_p1020_Taminiau2023-10-03T16:21:17Z Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes Taminiau, T.H. Stefani, F.D. Van Hulst, N.F. dark modes electric andmagnetic dipole emitters metal nanorods nanoantennas Optical antennas subradiance dark modes electric andmagnetic dipole emitters metal nanorods Nanoantennas Optical antennas Subradiances Mathematical models Nanorods Optical instruments Dipole antennas Optical antennas link objects to light. Here we derive an analytical model for the interaction of dipolar transitions with radiation through nanorod antenna modes, by modeling nanorods as cavities. The model includes radiation damping, accurately describes the complete emission process, and is summarized in a phase-matching equation. We analytically discuss the quantitative evolution of antenna modes, in particular the gradual emergence of subradiant, super-radiant, and dark modes, as antennas become increasingly more bound, i.e., plasmonic. Our description is valid for the interaction of nanorods with light in general and is thus widely applicable. © 2011 American Chemical Society. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_15306984_v11_n3_p1020_Taminiau
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic dark modes
electric andmagnetic dipole emitters
metal nanorods
nanoantennas
Optical antennas
subradiance
dark modes
electric andmagnetic dipole emitters
metal nanorods
Nanoantennas
Optical antennas
Subradiances
Mathematical models
Nanorods
Optical instruments
Dipole antennas
spellingShingle dark modes
electric andmagnetic dipole emitters
metal nanorods
nanoantennas
Optical antennas
subradiance
dark modes
electric andmagnetic dipole emitters
metal nanorods
Nanoantennas
Optical antennas
Subradiances
Mathematical models
Nanorods
Optical instruments
Dipole antennas
Taminiau, T.H.
Stefani, F.D.
Van Hulst, N.F.
Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes
topic_facet dark modes
electric andmagnetic dipole emitters
metal nanorods
nanoantennas
Optical antennas
subradiance
dark modes
electric andmagnetic dipole emitters
metal nanorods
Nanoantennas
Optical antennas
Subradiances
Mathematical models
Nanorods
Optical instruments
Dipole antennas
description Optical antennas link objects to light. Here we derive an analytical model for the interaction of dipolar transitions with radiation through nanorod antenna modes, by modeling nanorods as cavities. The model includes radiation damping, accurately describes the complete emission process, and is summarized in a phase-matching equation. We analytically discuss the quantitative evolution of antenna modes, in particular the gradual emergence of subradiant, super-radiant, and dark modes, as antennas become increasingly more bound, i.e., plasmonic. Our description is valid for the interaction of nanorods with light in general and is thus widely applicable. © 2011 American Chemical Society.
format JOUR
author Taminiau, T.H.
Stefani, F.D.
Van Hulst, N.F.
author_facet Taminiau, T.H.
Stefani, F.D.
Van Hulst, N.F.
author_sort Taminiau, T.H.
title Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes
title_short Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes
title_full Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes
title_fullStr Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes
title_full_unstemmed Optical nanorod antennas modeled as cavities for dipolar emitters: Evolution of sub- and super-radiant modes
title_sort optical nanorod antennas modeled as cavities for dipolar emitters: evolution of sub- and super-radiant modes
url http://hdl.handle.net/20.500.12110/paper_15306984_v11_n3_p1020_Taminiau
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AT stefanifd opticalnanorodantennasmodeledascavitiesfordipolaremittersevolutionofsubandsuperradiantmodes
AT vanhulstnf opticalnanorodantennasmodeledascavitiesfordipolaremittersevolutionofsubandsuperradiantmodes
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