Fourier-Engineered Plasmonic Lattice Resonances

Theng Loo Lim; Yaswant Vaddi; M. Saad Bin-Alam; Lin Cheng; Rasoul Alaee; Jeremy Upham; Mikko J. Huttunen; Ksenia Dolgaleva; Orad Reshef; Robert W. Boyd

doi:10.1021/acsnano.1c10710

Fourier-Engineered Plasmonic Lattice Resonances

Theng Loo Lim
, Yaswant Vaddi
, M. Saad Bin-Alam
, Lin Cheng
, Rasoul Alaee
, Jeremy Upham
, Mikko J. Huttunen
, Ksenia Dolgaleva
, Orad Reshef^*
, Robert W. Boyd

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

28 Citations (Scopus)

8 Downloads (Pure)

Abstract

Resonances in optical systems are useful for many applications, such as frequency comb generation, optical filtering, and biosensing. However, many of these applications are difficult to implement in optical metasurfaces because traditional approaches for designing multiresonant nanostructures require significant computational and fabrication efforts. To address this challenge, we introduce the concept of Fourier lattice resonances (FLRs) in which multiple desired resonances can be chosen a priori and used to dictate the metasurface design. Because each resonance is supported by a distinct surface lattice mode, each can have a high quality factor. Here, we experimentally demonstrate several metasurfaces with flexibly placed resonances (e.g., at 1310 and 1550 nm) and Q-factors as high as 800 in a plasmonic platform. This flexible procedure requires only the computation of a single Fourier transform for its design, and is based on standard lithographic fabrication methods, allowing one to design and fabricate a metasurface to fit any specific, optical-cavity-based application. This work represents a step toward the complete control over the transmission spectrum of a metasurface.

Original language	English
Pages (from-to)	5696-5703
Number of pages	8
Journal	ACS Nano
Volume	16
Issue number	4
Early online date	31 Mar 2022
DOIs	https://doi.org/10.1021/acsnano.1c10710
Publication status	Published - 26 Apr 2022
Publication type	A1 Journal article-refereed

Funding

We acknowledge the help of Sabaa Rashid with imaging. We thank Brian T. Sullivan and Graham Carlow for fruitful discussions. Fabrication in this work was performed in part at the Centre for Research in Photonics at the University of Ottawa (CRPuO). This research was undertaken thanks in part to funding from the Canada First Research Excellence Fund and the Canada Research Chairs program. L.C. acknowledges the support of the China Scholarship Council. M.J.H. acknowledges the Flagship of Photonics Research and Innovation (PREIN) funded by the Academy of Finland (Grant No. 320165). R.A. acknowledges support from the Alexander von Humboldt Foundation through the Feodor Lynen Return Research Fellowship. We acknowledge the support of the Natural Sciences and Engineering Research Council of Canada (NSERC) (funding reference number RGPIN/2017-06880, RGPIN/2020-03989, 950-231657, and STPGP/521619-2018). A prereview version of the manuscript has been published on the arXiv preprint server: Theng-Loo Lim; Yaswant Vaddi; M Saad Bin-Alam; Lin Cheng; Rasoul Alaee; Jeremy Upham; Mikko J Huttunen; Ksenia Dolgaleva; Orad Reshef; Robert W Boyd, Fourier-Engineered Plasmonic Lattice Resonances, 2021, 2112.11625, arXiv.org , https://arxiv.org/abs/2112.11625 (accessed December 22, 2021).

Keywords

lattice resonances
metasurfaces
nanoparticle arrays
nanophotonics
plasmonics

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

General Materials Science
General Engineering
General Physics and Astronomy

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10.1021/acsnano.1c10710

2112.11625-1
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Accepted author manuscript, 1.35 MBLicence: Unspecified

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Cite this

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title = "Fourier-Engineered Plasmonic Lattice Resonances",

abstract = "Resonances in optical systems are useful for many applications, such as frequency comb generation, optical filtering, and biosensing. However, many of these applications are difficult to implement in optical metasurfaces because traditional approaches for designing multiresonant nanostructures require significant computational and fabrication efforts. To address this challenge, we introduce the concept of Fourier lattice resonances (FLRs) in which multiple desired resonances can be chosen a priori and used to dictate the metasurface design. Because each resonance is supported by a distinct surface lattice mode, each can have a high quality factor. Here, we experimentally demonstrate several metasurfaces with flexibly placed resonances (e.g., at 1310 and 1550 nm) and Q-factors as high as 800 in a plasmonic platform. This flexible procedure requires only the computation of a single Fourier transform for its design, and is based on standard lithographic fabrication methods, allowing one to design and fabricate a metasurface to fit any specific, optical-cavity-based application. This work represents a step toward the complete control over the transmission spectrum of a metasurface.",

keywords = "lattice resonances, metasurfaces, nanoparticle arrays, nanophotonics, plasmonics",

author = "Lim, \{Theng Loo\} and Yaswant Vaddi and Bin-Alam, \{M. Saad\} and Lin Cheng and Rasoul Alaee and Jeremy Upham and Huttunen, \{Mikko J.\} and Ksenia Dolgaleva and Orad Reshef and Boyd, \{Robert W.\}",

note = "Funding Information: We acknowledge the help of Sabaa Rashid with imaging. We thank Brian T. Sullivan and Graham Carlow for fruitful discussions. Fabrication in this work was performed in part at the Centre for Research in Photonics at the University of Ottawa (CRPuO). This research was undertaken thanks in part to funding from the Canada First Research Excellence Fund and the Canada Research Chairs program. L.C. acknowledges the support of the China Scholarship Council. M.J.H. acknowledges the Flagship of Photonics Research and Innovation (PREIN) funded by the Academy of Finland (Grant No. 320165). R.A. acknowledges support from the Alexander von Humboldt Foundation through the Feodor Lynen Return Research Fellowship. We acknowledge the support of the Natural Sciences and Engineering Research Council of Canada (NSERC) (funding reference number RGPIN/2017-06880, RGPIN/2020-03989, 950-231657, and STPGP/521619-2018). A prereview version of the manuscript has been published on the arXiv preprint server: Theng-Loo Lim; Yaswant Vaddi; M Saad Bin-Alam; Lin Cheng; Rasoul Alaee; Jeremy Upham; Mikko J Huttunen; Ksenia Dolgaleva; Orad Reshef; Robert W Boyd, Fourier-Engineered Plasmonic Lattice Resonances, 2021, 2112.11625, arXiv.org , https://arxiv.org/abs/2112.11625 (accessed December 22, 2021). Publisher Copyright: {\textcopyright} 2021 American Chemical Society. All rights reserved.",

year = "2022",

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day = "26",

doi = "10.1021/acsnano.1c10710",

language = "English",

volume = "16",

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AU - Vaddi, Yaswant

AU - Bin-Alam, M. Saad

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AU - Upham, Jeremy

AU - Huttunen, Mikko J.

AU - Dolgaleva, Ksenia

AU - Reshef, Orad

AU - Boyd, Robert W.

N1 - Funding Information: We acknowledge the help of Sabaa Rashid with imaging. We thank Brian T. Sullivan and Graham Carlow for fruitful discussions. Fabrication in this work was performed in part at the Centre for Research in Photonics at the University of Ottawa (CRPuO). This research was undertaken thanks in part to funding from the Canada First Research Excellence Fund and the Canada Research Chairs program. L.C. acknowledges the support of the China Scholarship Council. M.J.H. acknowledges the Flagship of Photonics Research and Innovation (PREIN) funded by the Academy of Finland (Grant No. 320165). R.A. acknowledges support from the Alexander von Humboldt Foundation through the Feodor Lynen Return Research Fellowship. We acknowledge the support of the Natural Sciences and Engineering Research Council of Canada (NSERC) (funding reference number RGPIN/2017-06880, RGPIN/2020-03989, 950-231657, and STPGP/521619-2018). A prereview version of the manuscript has been published on the arXiv preprint server: Theng-Loo Lim; Yaswant Vaddi; M Saad Bin-Alam; Lin Cheng; Rasoul Alaee; Jeremy Upham; Mikko J Huttunen; Ksenia Dolgaleva; Orad Reshef; Robert W Boyd, Fourier-Engineered Plasmonic Lattice Resonances, 2021, 2112.11625, arXiv.org , https://arxiv.org/abs/2112.11625 (accessed December 22, 2021). Publisher Copyright: © 2021 American Chemical Society. All rights reserved.

PY - 2022/4/26

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N2 - Resonances in optical systems are useful for many applications, such as frequency comb generation, optical filtering, and biosensing. However, many of these applications are difficult to implement in optical metasurfaces because traditional approaches for designing multiresonant nanostructures require significant computational and fabrication efforts. To address this challenge, we introduce the concept of Fourier lattice resonances (FLRs) in which multiple desired resonances can be chosen a priori and used to dictate the metasurface design. Because each resonance is supported by a distinct surface lattice mode, each can have a high quality factor. Here, we experimentally demonstrate several metasurfaces with flexibly placed resonances (e.g., at 1310 and 1550 nm) and Q-factors as high as 800 in a plasmonic platform. This flexible procedure requires only the computation of a single Fourier transform for its design, and is based on standard lithographic fabrication methods, allowing one to design and fabricate a metasurface to fit any specific, optical-cavity-based application. This work represents a step toward the complete control over the transmission spectrum of a metasurface.

AB - Resonances in optical systems are useful for many applications, such as frequency comb generation, optical filtering, and biosensing. However, many of these applications are difficult to implement in optical metasurfaces because traditional approaches for designing multiresonant nanostructures require significant computational and fabrication efforts. To address this challenge, we introduce the concept of Fourier lattice resonances (FLRs) in which multiple desired resonances can be chosen a priori and used to dictate the metasurface design. Because each resonance is supported by a distinct surface lattice mode, each can have a high quality factor. Here, we experimentally demonstrate several metasurfaces with flexibly placed resonances (e.g., at 1310 and 1550 nm) and Q-factors as high as 800 in a plasmonic platform. This flexible procedure requires only the computation of a single Fourier transform for its design, and is based on standard lithographic fabrication methods, allowing one to design and fabricate a metasurface to fit any specific, optical-cavity-based application. This work represents a step toward the complete control over the transmission spectrum of a metasurface.

KW - lattice resonances

KW - metasurfaces

KW - nanoparticle arrays

KW - nanophotonics

KW - plasmonics

U2 - 10.1021/acsnano.1c10710

DO - 10.1021/acsnano.1c10710

M3 - Article

AN - SCOPUS:85127918705

SN - 1936-0851

VL - 16

SP - 5696

EP - 5703

JO - ACS Nano

JF - ACS Nano

IS - 4

ER -

Fourier-Engineered Plasmonic Lattice Resonances

Abstract

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