Single-molecule optomechanics in “picocavities”

Felix Benz; Mikolaj K. Schmidt; Alexander Dreismann; Rohit Chikkaraddy; Yao Zhang; Angela Demetriadou; Cloudy Carnegie; Hamid Ohadi; Bart De Nijs; Ruben Esteban; Javier Aizpurua; Jeremy J. Baumberg

doi:10.1126/science.aah5243

Single-molecule optomechanics in “picocavities”

Felix Benz, Mikolaj K. Schmidt, Alexander Dreismann, Rohit Chikkaraddy, Yao Zhang, Angela Demetriadou, Cloudy Carnegie, Hamid Ohadi, Bart De Nijs, Ruben Esteban, Javier Aizpurua, Jeremy J. Baumberg

Physics and Astronomy

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

320 Citations (Scopus)

Abstract

Trapping light with noble metal nanostructures overcomes the diffraction limit and can confine light to volumes typically on the order of 30 cubic nanometers. We found that individual atomic features inside the gap of a plasmonic nanoassembly can localize light to volumes well below 1 cubic nanometer (“picocavities”), enabling optical experiments on the atomic scale. These atomic features are dynamically formed and disassembled by laser irradiation. Although unstable at room temperature, picocavities can be stabilized at cryogenic temperatures, allowing single atomic cavities to be probed for many minutes. Unlike traditional optomechanical resonators, such extreme optical confinement yields a factor of 106 enhancement of optomechanical coupling between the picocavity field and vibrations of individual molecular bonds. This work sets the basis for developing nanoscale nonlinear quantum optics on the single-molecule level.

Original language	English
Pages (from-to)	726-729
Number of pages	4
Journal	Science
Volume	354
Issue number	6313
DOIs	https://doi.org/10.1126/science.aah5243
Publication status	Published - 11 Nov 2016

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title = "Single-molecule optomechanics in “picocavities”",

abstract = "Trapping light with noble metal nanostructures overcomes the diffraction limit and can confine light to volumes typically on the order of 30 cubic nanometers. We found that individual atomic features inside the gap of a plasmonic nanoassembly can localize light to volumes well below 1 cubic nanometer (“picocavities”), enabling optical experiments on the atomic scale. These atomic features are dynamically formed and disassembled by laser irradiation. Although unstable at room temperature, picocavities can be stabilized at cryogenic temperatures, allowing single atomic cavities to be probed for many minutes. Unlike traditional optomechanical resonators, such extreme optical confinement yields a factor of 106 enhancement of optomechanical coupling between the picocavity field and vibrations of individual molecular bonds. This work sets the basis for developing nanoscale nonlinear quantum optics on the single-molecule level.",

author = "Felix Benz and Schmidt, {Mikolaj K.} and Alexander Dreismann and Rohit Chikkaraddy and Yao Zhang and Angela Demetriadou and Cloudy Carnegie and Hamid Ohadi and {De Nijs}, Bart and Ruben Esteban and Javier Aizpurua and Baumberg, {Jeremy J.}",

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doi = "10.1126/science.aah5243",

language = "English",

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T1 - Single-molecule optomechanics in “picocavities”

AU - Benz, Felix

AU - Schmidt, Mikolaj K.

AU - Dreismann, Alexander

AU - Chikkaraddy, Rohit

AU - Zhang, Yao

AU - Demetriadou, Angela

AU - Carnegie, Cloudy

AU - Ohadi, Hamid

AU - De Nijs, Bart

AU - Esteban, Ruben

AU - Aizpurua, Javier

AU - Baumberg, Jeremy J.

PY - 2016/11/11

Y1 - 2016/11/11

N2 - Trapping light with noble metal nanostructures overcomes the diffraction limit and can confine light to volumes typically on the order of 30 cubic nanometers. We found that individual atomic features inside the gap of a plasmonic nanoassembly can localize light to volumes well below 1 cubic nanometer (“picocavities”), enabling optical experiments on the atomic scale. These atomic features are dynamically formed and disassembled by laser irradiation. Although unstable at room temperature, picocavities can be stabilized at cryogenic temperatures, allowing single atomic cavities to be probed for many minutes. Unlike traditional optomechanical resonators, such extreme optical confinement yields a factor of 106 enhancement of optomechanical coupling between the picocavity field and vibrations of individual molecular bonds. This work sets the basis for developing nanoscale nonlinear quantum optics on the single-molecule level.

AB - Trapping light with noble metal nanostructures overcomes the diffraction limit and can confine light to volumes typically on the order of 30 cubic nanometers. We found that individual atomic features inside the gap of a plasmonic nanoassembly can localize light to volumes well below 1 cubic nanometer (“picocavities”), enabling optical experiments on the atomic scale. These atomic features are dynamically formed and disassembled by laser irradiation. Although unstable at room temperature, picocavities can be stabilized at cryogenic temperatures, allowing single atomic cavities to be probed for many minutes. Unlike traditional optomechanical resonators, such extreme optical confinement yields a factor of 106 enhancement of optomechanical coupling between the picocavity field and vibrations of individual molecular bonds. This work sets the basis for developing nanoscale nonlinear quantum optics on the single-molecule level.

UR - https://spiral.imperial.ac.uk/handle/10044/1/42438

U2 - 10.1126/science.aah5243

DO - 10.1126/science.aah5243

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VL - 354

SP - 726

EP - 729

JO - Science

JF - Science

IS - 6313

ER -

Single-molecule optomechanics in “picocavities”

Abstract

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