Full control of plasmonic nanocavities using gold decahedra-on-mirror constructs with monodisperse facets

Shu Hu; Eoin Elliott; Ana Sanchez-Iglesias; Junyang  Huang; Chenang Guo; Yidong Hou; Marlous  Kamp; Eric S.A. Goerlitzer; Kalun Bedingfield; Bart De Nijs; Jialong Peng; Angela Demetriadou; Louis M. Liz-Marzan; Jeremy J. Baumberg

doi:10.1002/advs.202207178

Full control of plasmonic nanocavities using gold decahedra-on-mirror constructs with monodisperse facets

Shu Hu, Eoin Elliott, Ana Sanchez-Iglesias, Junyang Huang, Chenang Guo, Yidong Hou, Marlous Kamp, Eric S.A. Goerlitzer, Kalun Bedingfield, Bart De Nijs, Jialong Peng, Angela Demetriadou, Louis M. Liz-Marzan, Jeremy J. Baumberg^*

^*Corresponding author for this work

Physics and Astronomy

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Abstract

Bottom-up assembly of nanoparticle-on-mirror (NPoM) nanocavities enables precise inter-metal gap control down to ≈ 0.4 nm for confining light to sub-nanometer scales, thereby opening opportunities for developing innovative nanophotonic devices. However limited understanding, prediction, and optimization of light coupling and the difficulty of controlling nanoparticle facet shapes restricts the use of such building blocks. Here, an ultraprecise symmetry-breaking plasmonic nanocavity based on gold nanodecahedra is presented, to form the nanodecahedron-on-mirror (NDoM) which shows highly consistent cavity modes and fields. By characterizing > 20 000 individual NDoMs, the variability of light in/output coupling is thoroughly explored and a set of robust higher-order plasmonic whispering gallery modes uniquely localized at the edges of the triangular facet in contact with the metallic substrate is found. Assisted by quasinormal mode simulations, systematic elaboration of NDoMs is proposed to give nanocavities with near hundred-fold enhanced radiative efficiencies. Such systematically designed and precisely-assembled metallic nanocavities will find broad application in nanophotonic devices, optomechanics, and surface science.

Original language	English
Article number	2207178
Journal	Advanced Science
Early online date	3 Feb 2023
DOIs	https://doi.org/10.1002/advs.202207178
Publication status	E-pub ahead of print - 3 Feb 2023

Keywords

plasmonic nanocavity
gold decahedron
nanophotonics
metal nanoparticle
picocavity
surface-enhanced Raman spectroscopy (SERS)
surface‐enhanced Raman spectroscopy
Research Articles
Research Article

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Hu, S., Elliott, E., Sanchez-Iglesias, A., Huang, J., Guo, C., Hou, Y., Kamp, M., Goerlitzer, E. S. A., Bedingfield, K., De Nijs, B., Peng, J., Demetriadou, A., Liz-Marzan, L. M., & Baumberg, J. J. (2023). Full control of plasmonic nanocavities using gold decahedra-on-mirror constructs with monodisperse facets. Advanced Science, Article 2207178. Advance online publication. https://doi.org/10.1002/advs.202207178

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title = "Full control of plasmonic nanocavities using gold decahedra-on-mirror constructs with monodisperse facets",

abstract = "Bottom-up assembly of nanoparticle-on-mirror (NPoM) nanocavities enables precise inter-metal gap control down to ≈ 0.4 nm for confining light to sub-nanometer scales, thereby opening opportunities for developing innovative nanophotonic devices. However limited understanding, prediction, and optimization of light coupling and the difficulty of controlling nanoparticle facet shapes restricts the use of such building blocks. Here, an ultraprecise symmetry-breaking plasmonic nanocavity based on gold nanodecahedra is presented, to form the nanodecahedron-on-mirror (NDoM) which shows highly consistent cavity modes and fields. By characterizing > 20 000 individual NDoMs, the variability of light in/output coupling is thoroughly explored and a set of robust higher-order plasmonic whispering gallery modes uniquely localized at the edges of the triangular facet in contact with the metallic substrate is found. Assisted by quasinormal mode simulations, systematic elaboration of NDoMs is proposed to give nanocavities with near hundred-fold enhanced radiative efficiencies. Such systematically designed and precisely-assembled metallic nanocavities will find broad application in nanophotonic devices, optomechanics, and surface science.",

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author = "Shu Hu and Eoin Elliott and Ana Sanchez-Iglesias and Junyang Huang and Chenang Guo and Yidong Hou and Marlous Kamp and Goerlitzer, {Eric S.A.} and Kalun Bedingfield and {De Nijs}, Bart and Jialong Peng and Angela Demetriadou and Liz-Marzan, {Louis M.} and Baumberg, {Jeremy J.}",

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doi = "10.1002/advs.202207178",

language = "English",

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AU - Hu, Shu

AU - Elliott, Eoin

AU - Sanchez-Iglesias, Ana

AU - Huang, Junyang

AU - Guo, Chenang

AU - Hou, Yidong

AU - Kamp, Marlous

AU - Goerlitzer, Eric S.A.

AU - Bedingfield, Kalun

AU - De Nijs, Bart

AU - Peng, Jialong

AU - Demetriadou, Angela

AU - Liz-Marzan, Louis M.

AU - Baumberg, Jeremy J.

PY - 2023/2/3

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N2 - Bottom-up assembly of nanoparticle-on-mirror (NPoM) nanocavities enables precise inter-metal gap control down to ≈ 0.4 nm for confining light to sub-nanometer scales, thereby opening opportunities for developing innovative nanophotonic devices. However limited understanding, prediction, and optimization of light coupling and the difficulty of controlling nanoparticle facet shapes restricts the use of such building blocks. Here, an ultraprecise symmetry-breaking plasmonic nanocavity based on gold nanodecahedra is presented, to form the nanodecahedron-on-mirror (NDoM) which shows highly consistent cavity modes and fields. By characterizing > 20 000 individual NDoMs, the variability of light in/output coupling is thoroughly explored and a set of robust higher-order plasmonic whispering gallery modes uniquely localized at the edges of the triangular facet in contact with the metallic substrate is found. Assisted by quasinormal mode simulations, systematic elaboration of NDoMs is proposed to give nanocavities with near hundred-fold enhanced radiative efficiencies. Such systematically designed and precisely-assembled metallic nanocavities will find broad application in nanophotonic devices, optomechanics, and surface science.

AB - Bottom-up assembly of nanoparticle-on-mirror (NPoM) nanocavities enables precise inter-metal gap control down to ≈ 0.4 nm for confining light to sub-nanometer scales, thereby opening opportunities for developing innovative nanophotonic devices. However limited understanding, prediction, and optimization of light coupling and the difficulty of controlling nanoparticle facet shapes restricts the use of such building blocks. Here, an ultraprecise symmetry-breaking plasmonic nanocavity based on gold nanodecahedra is presented, to form the nanodecahedron-on-mirror (NDoM) which shows highly consistent cavity modes and fields. By characterizing > 20 000 individual NDoMs, the variability of light in/output coupling is thoroughly explored and a set of robust higher-order plasmonic whispering gallery modes uniquely localized at the edges of the triangular facet in contact with the metallic substrate is found. Assisted by quasinormal mode simulations, systematic elaboration of NDoMs is proposed to give nanocavities with near hundred-fold enhanced radiative efficiencies. Such systematically designed and precisely-assembled metallic nanocavities will find broad application in nanophotonic devices, optomechanics, and surface science.

KW - plasmonic nanocavity

KW - gold decahedron

KW - nanophotonics

KW - metal nanoparticle

KW - picocavity

KW - surface-enhanced Raman spectroscopy (SERS)

KW - surface‐enhanced Raman spectroscopy

KW - Research Articles

KW - Research Article

U2 - 10.1002/advs.202207178

DO - 10.1002/advs.202207178

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JO - Advanced Science

JF - Advanced Science

M1 - 2207178

ER -

Full control of plasmonic nanocavities using gold decahedra-on-mirror constructs with monodisperse facets

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