Brillouin cavity optomechanics with microfluidic devices

Gaurav Bahl; Kyu Hyun Kim; Wonsuk Lee; Jing Liu; Xudong Fan; Tal Carmon

doi:10.1038/ncomms2994

Brillouin cavity optomechanics with microfluidic devices

Gaurav Bahl, Kyu Hyun Kim, Wonsuk Lee, Jing Liu, Xudong Fan, Tal Carmon

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

Abstract

Cavity optomechanics allows the parametric coupling of phonon- and photon-modes in microresonators and is presently investigated in a broad variety of solid-state systems. Optomechanics with superfluids has been proposed as a path towards ultra-low optical- and mechanical-dissipation. However, there have been no optomechanics experiments reported with non-solid phases of matter. Direct liquid immersion of optomechanics experiments is challenging, as the acoustic energy simply leaks out to the higher-impedance liquid surrounding the device. Here we confine liquids within hollow resonators to circumvent this issue and to enable optical excitation of mechanical whispering-gallery modes at frequencies ranging from 2 to 11,000 MHz. Our device enables optomechanical investigation with liquids, while light is conventionally coupled from the outer dry side of the capillary, and liquids are provided by means of a standard microfluidic inlet.

Original language	English
Article number	1994
Journal	Nature Communications
Volume	4
DOIs	https://doi.org/10.1038/ncomms2994
State	Published - 7 Jun 2013
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/ncomms2994

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title = "Brillouin cavity optomechanics with microfluidic devices",

abstract = "Cavity optomechanics allows the parametric coupling of phonon- and photon-modes in microresonators and is presently investigated in a broad variety of solid-state systems. Optomechanics with superfluids has been proposed as a path towards ultra-low optical- and mechanical-dissipation. However, there have been no optomechanics experiments reported with non-solid phases of matter. Direct liquid immersion of optomechanics experiments is challenging, as the acoustic energy simply leaks out to the higher-impedance liquid surrounding the device. Here we confine liquids within hollow resonators to circumvent this issue and to enable optical excitation of mechanical whispering-gallery modes at frequencies ranging from 2 to 11,000 MHz. Our device enables optomechanical investigation with liquids, while light is conventionally coupled from the outer dry side of the capillary, and liquids are provided by means of a standard microfluidic inlet.",

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AU - Bahl, Gaurav

AU - Kim, Kyu Hyun

AU - Lee, Wonsuk

AU - Liu, Jing

AU - Fan, Xudong

AU - Carmon, Tal

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AB - Cavity optomechanics allows the parametric coupling of phonon- and photon-modes in microresonators and is presently investigated in a broad variety of solid-state systems. Optomechanics with superfluids has been proposed as a path towards ultra-low optical- and mechanical-dissipation. However, there have been no optomechanics experiments reported with non-solid phases of matter. Direct liquid immersion of optomechanics experiments is challenging, as the acoustic energy simply leaks out to the higher-impedance liquid surrounding the device. Here we confine liquids within hollow resonators to circumvent this issue and to enable optical excitation of mechanical whispering-gallery modes at frequencies ranging from 2 to 11,000 MHz. Our device enables optomechanical investigation with liquids, while light is conventionally coupled from the outer dry side of the capillary, and liquids are provided by means of a standard microfluidic inlet.

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JF - Nature Communications

M1 - 1994

ER -

Brillouin cavity optomechanics with microfluidic devices

Abstract

All Science Journal Classification (ASJC) codes

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