Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber

Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber

It is interesting to pose the question: How best to design an optomechanical device, with no electronics, optical cavity, or laser gain, that will self-oscillate when pumped in a single pass with only a few mW of single-frequency laser power? One might begin with a mechanically resonant and highly c...

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Main Authors: J. R. Koehler, R. E. Noskov, A. A. Sukhorukov, A. Butsch, D. Novoa, P. St. J. Russell
Format: Article
Language:English
Published: AIP Publishing LLC 2016-08-01
Series:APL Photonics
Online Access:http://dx.doi.org/10.1063/1.4953373
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spelling doaj-3b808ba5ffac45eead90cd07048b1cb32020-11-25T01:16:07ZengAIP Publishing LLCAPL Photonics2378-09672016-08-0115056101056101-1210.1063/1.4953373004603APPResolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiberJ. R. Koehler0R. E. Noskov1A. A. Sukhorukov2A. Butsch3D. Novoa4P. St. J. Russell5Max-Planck Institute for the Science of Light, Guenther-Scharowsky-Str. 1, 91058 Erlangen, GermanyMax-Planck Institute for the Science of Light, Guenther-Scharowsky-Str. 1, 91058 Erlangen, GermanyMax-Planck Institute for the Science of Light, Guenther-Scharowsky-Str. 1, 91058 Erlangen, GermanyMax-Planck Institute for the Science of Light, Guenther-Scharowsky-Str. 1, 91058 Erlangen, GermanyMax-Planck Institute for the Science of Light, Guenther-Scharowsky-Str. 1, 91058 Erlangen, GermanyMax-Planck Institute for the Science of Light, Guenther-Scharowsky-Str. 1, 91058 Erlangen, GermanyIt is interesting to pose the question: How best to design an optomechanical device, with no electronics, optical cavity, or laser gain, that will self-oscillate when pumped in a single pass with only a few mW of single-frequency laser power? One might begin with a mechanically resonant and highly compliant system offering very high optomechanical gain. Such a system, when pumped by single-frequency light, might self-oscillate at its resonant frequency. It is well-known, however, that this will occur only if the group velocity dispersion of the light is high enough so that phonons causing pump-to-Stokes conversion are sufficiently dissimilar to those causing pump-to-anti-Stokes conversion. Recently it was reported that two light-guiding membranes 20 μm wide, ∼500 nm thick and spaced by ∼500 nm, suspended inside a glass fiber capillary, oscillated spontaneously at its mechanical resonant frequency (∼6 MHz) when pumped with only a few mW of single-frequency light. This was surprising, since perfect Raman gain suppression would be expected. In detailed measurements, using an interferometric side-probing technique capable of resolving nanoweb movements as small as 10 pm, we map out the vibrations along the fiber and show that stimulated intermodal scattering to a higher-order optical mode frustrates gain suppression, permitting the structure to self-oscillate. A detailed theoretical analysis confirms this picture. This novel mechanism makes possible the design of single-pass optomechanical oscillators that require only a few mW of optical power, no electronics nor any optical resonator. The design could also be implemented in silicon or any other suitable material.http://dx.doi.org/10.1063/1.4953373
collection DOAJ
language English
format Article
sources DOAJ
author J. R. Koehler
R. E. Noskov
A. A. Sukhorukov
A. Butsch
D. Novoa
P. St. J. Russell
spellingShingle J. R. Koehler
R. E. Noskov
A. A. Sukhorukov
A. Butsch
D. Novoa
P. St. J. Russell
Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
APL Photonics
author_facet J. R. Koehler
R. E. Noskov
A. A. Sukhorukov
A. Butsch
D. Novoa
P. St. J. Russell
author_sort J. R. Koehler
title Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
title_short Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
title_full Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
title_fullStr Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
title_full_unstemmed Resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
title_sort resolving the mystery of milliwatt-threshold opto-mechanical self-oscillation in dual-nanoweb fiber
publisher AIP Publishing LLC
series APL Photonics
issn 2378-0967
publishDate 2016-08-01
description It is interesting to pose the question: How best to design an optomechanical device, with no electronics, optical cavity, or laser gain, that will self-oscillate when pumped in a single pass with only a few mW of single-frequency laser power? One might begin with a mechanically resonant and highly compliant system offering very high optomechanical gain. Such a system, when pumped by single-frequency light, might self-oscillate at its resonant frequency. It is well-known, however, that this will occur only if the group velocity dispersion of the light is high enough so that phonons causing pump-to-Stokes conversion are sufficiently dissimilar to those causing pump-to-anti-Stokes conversion. Recently it was reported that two light-guiding membranes 20 μm wide, ∼500 nm thick and spaced by ∼500 nm, suspended inside a glass fiber capillary, oscillated spontaneously at its mechanical resonant frequency (∼6 MHz) when pumped with only a few mW of single-frequency light. This was surprising, since perfect Raman gain suppression would be expected. In detailed measurements, using an interferometric side-probing technique capable of resolving nanoweb movements as small as 10 pm, we map out the vibrations along the fiber and show that stimulated intermodal scattering to a higher-order optical mode frustrates gain suppression, permitting the structure to self-oscillate. A detailed theoretical analysis confirms this picture. This novel mechanism makes possible the design of single-pass optomechanical oscillators that require only a few mW of optical power, no electronics nor any optical resonator. The design could also be implemented in silicon or any other suitable material.
url http://dx.doi.org/10.1063/1.4953373
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