Superfluid Brillouin optomechanics

Kashkanova, Anna; Shkarin, Alexey; Brown, Clair; Flowers-Jacobs, Nathan E.; Childress, Lilian; Hoch, S. W.; Hohmann, Leander; Ott, Konstantin; Reichel, Jakob; Harris, Jack

doi:10.1038/nphys3900

Cited by 62 publications

(97 citation statements)

References 55 publications

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“…The predicted cooperativity displays a strong dependence on film thickness, reaching large values above unity, with = C 6 0 for d=30 nm. This value -on par with the state-of-the-art in optomechanical systems [2,48]-would represent a significant increase in performance compared to existing superfluid optomechanics systems; it corresponds for instance to an over four orders of magnitude increase over recently demonstrated superfluid helium filled fiber cavities [12]. High cooperativities and large optomechanical coupling rates are essential for such applications as ultra-high precision quantum-limited measurement [1] of the superfluid motion, mechanical ground state cooling [2] and accessing the strong coupling regime [49,50] between light and third sound excitations.…”

Section: Influence Of Resonator Radiusmentioning

confidence: 97%

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Theoretical framework for thin film superfluid optomechanics: towards the quantum regime

et al. 2016

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Excitations in superfluid helium represent attractive mechanical degrees of freedom for cavity optomechanics schemes. Here we numerically and analytically investigate the properties of optomechanical resonators formed by thin films of superfluid 4 He covering micrometer-scale whispering gallery mode cavities. We predict that through proper optimization of the interaction between film and optical field, large optomechanical coupling rates p >ǵ 2 100 kHz 0 and single photon cooperativities > C 10 0 are achievable. Our analytical model reveals the unconventional behaviour of these thin films, such as thicker and heavier films exhibiting smaller effective mass and larger zero point motion. The optomechanical system outlined here provides access to unusual regimes such as > W g M 0 and opens the prospect of laser cooling a liquid into its quantum ground state.

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Section: Influence Of Resonator Radiusmentioning

confidence: 97%

“…To date, the majority of superfluid optomechanics schemes have relied on bulk helium, with implementations taking for example the form of a gram-scale resonator coupled to a superconducting microwave resonator [9], a capacitively detected superfluid Helmholtz resonator [11] or a helium-filled fiber cavity [12].…”

Section: Introductionmentioning

confidence: 99%

Theoretical framework for thin film superfluid optomechanics: towards the quantum regime

et al. 2016

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“…These cavities can achieve very small mode waists, which are advantageous for cavity quantum electrodynamics applications; so far, they have been coupled to atoms [11][12][13], ions [9,14], optomechanical systems [15,16], molecules [17], and crystalline defect centers [18][19][20]. Moreover, the light weight of the fiber mirror suggests that it should be possible to achieve a high bandwidth feedback loop for length stabilization of such a cavity.…”

Section: Introductionmentioning

confidence: 99%

High mechanical bandwidth fiber-coupled Fabry-Perot cavity

Janitz¹,

Ruf²,

Fontana³

et al. 2017

Opt. Express

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Fiber-based optical microcavities exhibit high quality factor and low mode volume resonances that make them attractive for coupling light to individual atoms or other microscopic systems. Moreover, their low mass should lead to excellent mechanical response up to high frequencies, opening the possibility for high bandwidth stabilization of the cavity length. Here, we demonstrate a locking bandwidth of 44 kHz achieved using a simple, compact design that exploits these properties. Owing to the simplicity of fiber feedthroughs and lack of free-space alignment, this design is inherently compatible with vacuum and cryogenic environments. We measure the transfer function of the feedback circuit (closed-loop) and the cavity mount itself (open-loop), which, combined with simulations of the mechanical response of our device, provide insight into underlying limitations of the design as well as further improvements that can be made.

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“…Liquid-based optomechanical devices can also be realized by filling [21][22][23][24] or coating [25] a solid electromagnetic cavity with a fluid. In this case only the mechanical degree of freedom is provided by the fluid, for example, as a density wave or surface wave that detunes the cavity by modulating the overlap between the liquid and the cavity mode.…”

Section: Introductionmentioning

confidence: 99%

“…In this case only the mechanical degree of freedom is provided by the fluid, for example, as a density wave or surface wave that detunes the cavity by modulating the overlap between the liquid and the cavity mode. This approach has been used at cryogenic temperatures with superfluid 4 He serving as the liquid [22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Cavity optomechanics in a levitated helium drop

et al. 2017

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We describe a proposal for a type of optomechanical system based on a drop of liquid helium that is magnetically levitated in vacuum. In the proposed device, the drop would serve three roles: its optical whispering-gallery modes would provide the optical cavity, its surface vibrations would constitute the mechanical element, and evaporation of He atoms from its surface would provide continuous refrigeration. We analyze the feasibility of such a system in light of previous experimental demonstrations of its essential components: magnetic levitation of mm-scale and cm-scale drops of liquid He, evaporative cooling of He droplets in vacuum, and coupling to high-quality optical whispering-gallery modes in a wide range of liquids. We find that the combination of these features could result in a device that approaches the single-photon strong-coupling regime, due to the high optical quality factors attainable at low temperatures. Moreover, the system offers a unique opportunity to use optical techniques to study the motion of a superfluid that is freely levitating in vacuum (in the case of 4 He). Alternatively, for a normal fluid drop of 3 He, we propose to exploit the coupling between the drop's rotations and vibrations to perform quantum nondemolition measurements of angular momentum.

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Superfluid Brillouin optomechanics

Cited by 62 publications

References 55 publications

Theoretical framework for thin film superfluid optomechanics: towards the quantum regime

Theoretical framework for thin film superfluid optomechanics: towards the quantum regime

High mechanical bandwidth fiber-coupled Fabry-Perot cavity

Cavity optomechanics in a levitated helium drop

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