Vibrational coupling in plasmonic molecules

Chongyue Yi; Pratiksha D. Dongare; Man Nung Su; Wenxiao Wang; Debadi Chakraborty; Fangfang Wen; Wei Shun Chang; John E. Sader; Peter Nordlander; Naomi J. Halas; Stephan Link

doi:10.1073/pnas.1712418114

Vibrational coupling in plasmonic molecules

Chongyue Yi, Pratiksha D. Dongare, Man Nung Su, Wenxiao Wang, Debadi Chakraborty, Fangfang Wen, Wei Shun Chang, John E. Sader, Peter Nordlander, Naomi J. Halas, Stephan Link

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

Abstract

Plasmon hybridization theory, inspired by molecular orbital theory, has been extremely successful in describing the near-field coupling in clusters of plasmonic nanoparticles, also known as plasmonic molecules. However, the vibrational modes of plasmonic molecules have been virtually unexplored. By designing precisely configured plasmonic molecules of varying complexity and probing them at the individual plasmonic molecule level, intramolecular coupling of acoustic modes, mediated by the underlying substrate, is observed. The strength of this coupling can be manipulated through the configuration of the plasmonic molecules. Surprisingly, classical continuum elastic theory fails to account for the experimental trends, which are well described by a simple coupled oscillator picture that assumes the vibrational coupling is mediated by coherent phonons with low energies. These findings provide a route to the systematic optical control of the gigahertz response of metallic nanostructures, opening the door to new optomechanical device strategies.

Original language	English (US)
Pages (from-to)	11621-11626
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	114
Issue number	44
DOIs	https://doi.org/10.1073/pnas.1712418114
State	Published - Oct 31 2017
Externally published	Yes

Keywords

Coherent phonon
Optomechanics
Plasmonics
Ultrafast spectroscopy

ASJC Scopus subject areas

General

Online availability

10.1073/pnas.1712418114

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title = "Vibrational coupling in plasmonic molecules",

abstract = "Plasmon hybridization theory, inspired by molecular orbital theory, has been extremely successful in describing the near-field coupling in clusters of plasmonic nanoparticles, also known as plasmonic molecules. However, the vibrational modes of plasmonic molecules have been virtually unexplored. By designing precisely configured plasmonic molecules of varying complexity and probing them at the individual plasmonic molecule level, intramolecular coupling of acoustic modes, mediated by the underlying substrate, is observed. The strength of this coupling can be manipulated through the configuration of the plasmonic molecules. Surprisingly, classical continuum elastic theory fails to account for the experimental trends, which are well described by a simple coupled oscillator picture that assumes the vibrational coupling is mediated by coherent phonons with low energies. These findings provide a route to the systematic optical control of the gigahertz response of metallic nanostructures, opening the door to new optomechanical device strategies.",

keywords = "Coherent phonon, Optomechanics, Plasmonics, Ultrafast spectroscopy",

author = "Chongyue Yi and Dongare, {Pratiksha D.} and Su, {Man Nung} and Wenxiao Wang and Debadi Chakraborty and Fangfang Wen and Chang, {Wei Shun} and Sader, {John E.} and Peter Nordlander and Halas, {Naomi J.} and Stephan Link",

note = "ACKNOWLEDGMENTS. This work was supported by Robert A. Welch Foundation Grants C-1222 (to P.N.), C-1220 (to N.J.H.), and C-1664 (to S.L.). P.N., N.J.H., and S.L. were supported by Army Grant MURI W911NF-12-1-0407 and Air Force Grant MURI FA9550-15-1-0022. S.L. was supported by National Science Foundation Grant ECCS-1608917. D.C. and J.E.S. were supported by the Australian Research Council (ARC) grants scheme and the ARC Centre of Excellence in Exciton Science.",

year = "2017",

month = oct,

day = "31",

doi = "10.1073/pnas.1712418114",

language = "English (US)",

volume = "114",

pages = "11621--11626",

journal = "Proceedings of the National Academy of Sciences of the United States of America",

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number = "44",

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TY - JOUR

T1 - Vibrational coupling in plasmonic molecules

AU - Yi, Chongyue

AU - Dongare, Pratiksha D.

AU - Su, Man Nung

AU - Wang, Wenxiao

AU - Chakraborty, Debadi

AU - Wen, Fangfang

AU - Chang, Wei Shun

AU - Sader, John E.

AU - Nordlander, Peter

AU - Halas, Naomi J.

AU - Link, Stephan

N1 - ACKNOWLEDGMENTS. This work was supported by Robert A. Welch Foundation Grants C-1222 (to P.N.), C-1220 (to N.J.H.), and C-1664 (to S.L.). P.N., N.J.H., and S.L. were supported by Army Grant MURI W911NF-12-1-0407 and Air Force Grant MURI FA9550-15-1-0022. S.L. was supported by National Science Foundation Grant ECCS-1608917. D.C. and J.E.S. were supported by the Australian Research Council (ARC) grants scheme and the ARC Centre of Excellence in Exciton Science.

PY - 2017/10/31

Y1 - 2017/10/31

N2 - Plasmon hybridization theory, inspired by molecular orbital theory, has been extremely successful in describing the near-field coupling in clusters of plasmonic nanoparticles, also known as plasmonic molecules. However, the vibrational modes of plasmonic molecules have been virtually unexplored. By designing precisely configured plasmonic molecules of varying complexity and probing them at the individual plasmonic molecule level, intramolecular coupling of acoustic modes, mediated by the underlying substrate, is observed. The strength of this coupling can be manipulated through the configuration of the plasmonic molecules. Surprisingly, classical continuum elastic theory fails to account for the experimental trends, which are well described by a simple coupled oscillator picture that assumes the vibrational coupling is mediated by coherent phonons with low energies. These findings provide a route to the systematic optical control of the gigahertz response of metallic nanostructures, opening the door to new optomechanical device strategies.

AB - Plasmon hybridization theory, inspired by molecular orbital theory, has been extremely successful in describing the near-field coupling in clusters of plasmonic nanoparticles, also known as plasmonic molecules. However, the vibrational modes of plasmonic molecules have been virtually unexplored. By designing precisely configured plasmonic molecules of varying complexity and probing them at the individual plasmonic molecule level, intramolecular coupling of acoustic modes, mediated by the underlying substrate, is observed. The strength of this coupling can be manipulated through the configuration of the plasmonic molecules. Surprisingly, classical continuum elastic theory fails to account for the experimental trends, which are well described by a simple coupled oscillator picture that assumes the vibrational coupling is mediated by coherent phonons with low energies. These findings provide a route to the systematic optical control of the gigahertz response of metallic nanostructures, opening the door to new optomechanical device strategies.

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KW - Optomechanics

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KW - Ultrafast spectroscopy

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Vibrational coupling in plasmonic molecules

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