Silicon microcavity arrays with open access and a finesse of half a million

Wachter, Georg; Kühn, Stefan; Minniberger, Stefan; Salter, C. L.; Asenbaum, Peter; Millen, James; Schneider, Michael; Schalko, J.; Schmid, U.; Felgner, André; Hüser, Dorothee; Arndt, Markus; Trupke, Michael

doi:10.1038/s41377-019-0145-y

Cited by 55 publications

(30 citation statements)

References 27 publications

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“…3 for more details). As predicted, the smaller the cavity length the larger the generated squeezing, with S reaching values well over 10 dB for sub-millimeter-sized cavities [48,50,51]. The results shown in Fig.…”

supporting

confidence: 76%

“…(1)]. This regime is within reach for levitated optomechanics [41,42], specifically for an optically levitated nanoparticle coupled via coherent scattering [43][44][45][46][47] to a microcavity [48][49][50][51] in the unresolved sideband regime. Our results are particularly timely due to recent experiments demonstrating groundstate cooling and quantum control of optically levitated nanoparticles in free space [52,53].…”

mentioning

confidence: 99%

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Mechanical squeezing via unstable dynamics in a microcavity

Kustura,

Gonzalez-Ballestero,

Sommer

et al. 2021

Preprint

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We theoretically show that strong mechanical quantum squeezing in a linear optomechanical system can be rapidly generated through the dynamical instability reached in the far red-detuned and ultrastrong coupling regime. We show that this mechanism, which harnesses unstable multimode quantum dynamics, is particularly suited to levitated optomechanics, and we argue for its feasibility for the case of a levitated nanoparticle coupled to a microcavity via coherent scattering. We predict that for sub-millimeter-sized cavities the particle motion, initially thermal and well above its ground state, becomes mechanically squeezed by tens of decibels on a microsecond timescale. Our results bring forth optical microcavities in the unresolved sideband regime as powerful mechanical squeezers for levitated nanoparticles, and hence as key tools for quantum-enhanced inertial and force sensing.

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supporting

confidence: 76%

mentioning

confidence: 99%

Mechanical squeezing via unstable dynamics in a microcavity

Kustura,

Gonzalez-Ballestero,

Sommer

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…The scalability, brightness, purity and collection efficiency of these single-photon emitters are key issues in bringing them closer to practical applications. A scalable photonic platform that houses singlephoton emitters integrated into photonic structures such as nanopillars [8], solid immersion lenses [9] or highquality optical microcavities [10] is thus beneficial.…”

Section: Introductionmentioning

confidence: 99%

A photonic platform hosting telecom photon emitters in silicon

Hollenbach¹,

Jagtap²,

Fowley³

et al. 2021

Preprint

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Silicon, a ubiquitous material in modern computing, is an emerging platform for realizing a source of indistinguishable single-photons on demand. The integration of recently discovered single-photon emitters in silicon into photonic structures, is advantageous to exploit their full potential for integrated photonic quantum technologies. Here, we show the integration of telecom photon emitters in a photonic platform consisting of silicon nanopillars. We developed a CMOS-compatible nanofabrication method, enabling the production of thousands of individual nanopillars per square millimeter with state-of-the-art photonic-circuit pitch, all the while being free of fabrication-related radiation damage defects. We found a waveguiding effect of the 1278 nm-G center emission along individual pillars accompanied by improved brightness, photoluminescence signal-to-noise ratio and photon extraction efficiency compared to that of bulk silicon. These results unlock clear pathways to monolithically integrating single-photon emitters into a photonic platform at a scale that matches the required pitch of quantum photonic circuits.

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“…To compete, bulky optomechanical experiments must be prototyped and miniaturised. This is now an active research area, where MEMS processes are used to create chip-scale silicon photonic structures on silicon-on-insulator wafers, resulting in sub-milimeter scale Fabry-Perot cavities, 16 evanescent strip waveguides replacing tapered optical fibers, 17 tethered photonic crystal membranes, 18 and suspended strings with ultrahigh mechanical quality factors. 19 The significant size reduction offered by optomechanical MEMS sensors, combined with their ability to reach displacement sensitivities on the order of 10 −18 mHz −1/2 , 7, 20 makes them a particularly disruptive technology.…”

Section: Introductionmentioning

confidence: 99%

Commercializing optomechanical sensors: from the classical to quantum regime

Barker

2019

Optical Trapping and Optical Micromanipulation XVI

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Cavity optomechanical systems show great promise as force and displacement sensors, with scope to operate across the classical to quantum regimes. I will discuss the commercial development of an optical whispering gallery mode (WGM) accelerometer, which relies on a dispersive and dissipative coupling between the cavity resonance and the motion of the cavity. The accelerometer operates at a sensitivity of micro-g Hz −1/2 (g=9.81 ms −2 ) with plans to approach nano-g Hz −1/2 through tailoring the mechanical and optical properties. I also describe the first prototype assembly, results from outdoor field-trials, and recent work using micro-electro-mechanical systems engineering to produce a chip-scale device.

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Silicon microcavity arrays with open access and a finesse of half a million

Cited by 55 publications

References 27 publications

Mechanical squeezing via unstable dynamics in a microcavity

Mechanical squeezing via unstable dynamics in a microcavity

A photonic platform hosting telecom photon emitters in silicon

Commercializing optomechanical sensors: from the classical to quantum regime

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