Manipulating light-matter interaction in a gold nanorod assembly by plasmonic coupling

The interaction of light with a single gold nanorod (GNR) depends strongly on the polarization and wavelength of the light. For isolated GNRs, the maximum of the polarization (wavelength)‐dependent linear and nonlinear absorption appear at the same excitation polarization (wavelength). Here, it is d...

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Bibliographic Details
Published in:Laser & photonics reviews 2016-09, Vol.10 (5), p.826-834
Main Authors: Li, Jin-Xiang, Xu, Yi, Dai, Qiao-Feng, Lan, Sheng, Tie, Shao-Long
Format: Article
Language:English
Subjects:
Absorption
Assembly
Coupling
Gold
gold nanorod assembly
Nanorods
Nanostructure
Photon absorption
Photons
plasmonic coupling
Plasmonics
Polarization
single-photon absorption
two-photon absorption
Wavelengths
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Summary:The interaction of light with a single gold nanorod (GNR) depends strongly on the polarization and wavelength of the light. For isolated GNRs, the maximum of the polarization (wavelength)‐dependent linear and nonlinear absorption appear at the same excitation polarization (wavelength). Here, it is demonstrated that these relationships can be manipulated in a GNR assembly composed of randomly distributed and oriented GNRs by controlling the plasmonic coupling strength between GNRs. It is revealed that the strongly localized modes resulting from the plasmonic coupling of GNRs play a crucial role in determining these relationships. For a GNR tetramer, it is shown by numerical simulation that the maximum two‐photon absorption achieved at a particular polarization can be switched to the minimum absorption and vice versa by controlling the coupling strength. More importantly, it is demonstrated both numerically and experimentally that the two‐photon‐absorption peak of a GNR assembly can be made to be different from its single‐photon‐absorption peak by increasing the coupling strength. Both properties are distinct from previous experimental observations. Our findings provide a useful guideline for engineering the interaction of light with complex plasmonic systems. It is well known that the maximum of the polarization (wavelength)‐dependent linear and nonlinear absorption appear at the same excitation polarization (wavelength) for isolated gold nanorods. Here, it is demonstrated that these intuitive relationships can be different in a GNR assembly composed of randomly distributed and oriented GNRs with plasmonic coupling. It is revealed that the strongly localized modes resulted from the plasmonic coupling of GNRs play a crucial role in determining these relationships.
ISSN:1863-8880
1863-8899
DOI:10.1002/lpor.201600143