Overwhelming Thermomechanical Motion with Microwave Radiation Pressure Shot Noise

Teufel, John; Lecocq, Florent; Simmonds, Raymond W.

doi:10.1103/physrevlett.116.013602

Cited by 71 publications

(66 citation statements)

References 33 publications

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“…The first challenge has been met by several cryogenic optomechanical [13,14] and electromechanical systems [15] (via resolved-sideband cooling [16]). The latter, corresponding to a measurement at the standard quantum limit (SQL) [17], remains outstanding; however, readout noise far below the zero-point displacement has been reported [18,19], as well as RPSN dominating the thermal force [20,21]. Reaching the SQL ultimately requires a 'Heisenberg-limited' displacement sensor for which the product of the read out noise and the total force noise is the minimum allowed by the uncertainty principle.…”

Section: Introductionmentioning

confidence: 99%

Near-Field Integration of a SiN Nanobeam and aSiO2Microcavity for Heisenberg-Limited Displacement Sensing

et al. 2016

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Placing a nanomechanical object in the evanescent near-field of a high-Q optical microcavity gives access to strong gradient forces and quantum-limited displacement readout, offering an attractive platform for both precision sensing technology and basic quantum optics research. Robustly implementing this platform is challenging, however, as it requires integrating optically smooth surfaces separated by λ/10. Here we describe an exceptionally high-cooperativity, single-chip optonanomechanical transducer based on a high-stress Si3N4 nanobeam monolithically integrated into the evanescent near-field of SiO2 microdisk cavity. Employing a novel vertical integration technique based on planarized sacrificial layers, we realize beam-disk gaps as little as 25 nm while maintaining mechanical Q × f > 10 12 Hz and intrinsic optical Q ∼ 10 7 . The combination of low loss, small gap, and parallel-plane geometry results in radio-frequency flexural modes with vacuum optomechanical coupling rates of 100 kHz, single-photon cooperativities in excess of unity, and large zero-point frequency (displacement) noise amplitudes of 10 kHz (fm) / √ Hz. In conjunction with the high power handling capacity of SiO2 and low extraneous substrate noise, the transducer performs particularly well as a sensor, with recent deployment in a 4 K cryostat realizing a displacement imprecision 40 dB below that at the standard quantum limit (SQL) and an imprecision-back-action product < 5 · (Wilson et. al., Nature 524, 325 (2015)). In this report we provide a comprehensive description of device design, fabrication, and characterization, with an emphasis on extending Heisenberg-limited readout to room temperature. Towards this end, we describe a room temperature experiment in which a displacement imprecision 32 dB below that at the SQL and an imprecision-back-action product < 60 · is achieved. Our results extend the outlook for measurement-based quantum control of nanomechanical oscillators and suggest an alternative platform for functionally-integrated "hybrid" quantum optomechanics.

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Section: Introductionmentioning

confidence: 99%

Near-Field Integration of a SiN Nanobeam and aSiO2Microcavity for Heisenberg-Limited Displacement Sensing

et al. 2016

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“…This sensitivity is rivaled only by techniques based on superconducting microwave electromechanical systems, which operate at ultra-low (T ≪ 1 K ) cryogenic temperatures [39,40]. Interest in this quantum domain has originally been motivated by observatories such as LIGO and can now, for the first time, be explored with optical and microwave experiments [3,9,15,41,42]. In addition, laser-based techniques can provide spatial imaging of mechanical displacement patterns.…”

Section: Resultsmentioning

confidence: 99%

Measuring and imaging nanomechanical motion with laser light

Barg¹,

Tsaturyan²,

Belhage³

et al. 2016

Appl. Phys. B

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We discuss several techniques based on laser-driven interferometers and cavities to measure nanomechanical motion. With increasing complexity, they achieve sensitivities reaching from thermal displacement amplitudes, typically at the picometer scale, all the way to the quantum regime, in which radiation pressure induces motion correlated with the quantum fluctuations of the probing light. We show that an imaging modality is readily provided by scanning laser interferometry, reaching a sensitivity on the order of $$10\, {\mathrm {fm/Hz^{1/2}}}$$ 10 fm / Hz 1 / 2 , and a transverse resolution down to $$2\,\upmu {\hbox {m}}$$ 2 μ m . We compare this approach with a less versatile, but faster (single-shot) dark-field imaging technique.

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“…On the feedback front, the question of how to optimally treat the measurement record before feeding back, is of prime importance. Section 5.1.1 addresses this problem; the simple filter used in chapters 3 and 4 can in fact be bettered using an optimal filter, at the expense of 5.1 This regime has now been accessed in at least one other experiment [295], where a Ω m = 2π · 9.3 MHz mechanical oscillator is measured using a microwave cavity interferometer operated at ≈ 100 mK. Red is the intrinsic mechanical susceptibility χ x , while blue is the susceptibility of the cold-damping filter χ −1 fb,cold ∝ −ig fb ΩΓ m , and green is the susceptibility of the optimal feedback filter χ fb,opt .…”

Section: Some Future Directionsmentioning

confidence: 99%

“…For large measurement strengths, quantum measurement back-action [294,295] should in principle exceed the ambient thermal force. As shown in fig.…”

Section: Heisenberg-uncertainty-limited Measurementmentioning

confidence: 99%

Quantum Limits on Measurement and Control of a Mechanical Oscillator

Sudhir

2018

Springer Theses

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PAR Vivishek SUDHIR JOSEPH CONRAD, Heart of DarknessExperimental physics demands a certain degree of manual dexterity, the patience to tolerate the mundane, and an inexhaustible supply of optimism. Tobias hired me to work on an immensely sophisticated experiment despite any proof of my possessing these qualities; I am indebted to him for the belief he has placed in me. I would also like to acknowledge his dedication to fostering an environment where the pursuit of science is unencumbered by other worldly concerns. Stefan, Ewold and Samuel bore the brunt of a theorist trying to perform delicate experiments; the stern, yet encouraging, stewardship of this trio ensured that I enjoyed the culture shock. Dal Wilson was more than a colleague and a post-doc; his pragmatic approach to physics provided the ideal counter-point in our attempts to forge a deeper understanding of things ranging from vibration isolation to the subtleties of quantum mechanics. Without the patient efforts of Amir, Ryan and Hendrik in designing, fabricating, and testing of devices, none of the results reported here would have been possible. I hope I have been able to bequeath a better vision of the future of our experiment to Sergey. Conversations with Alexey, Daniel and Nathan have enabled me to vicariously learn how to measure microwave "photons". John Jost once taught me how to decorate a Christmas tree; since then he has imparted some wisdom on frequency metrology, and some on atomic physics. Together with Dal, Victor and Caroline have probably spent the most time with me outside the lab; it was fun to exercise an air of social normalcy with this bunch. Christophe has been an amazing sparring partner on every subject capable of being brought under scientific scrutiny.The personal space required for the pursuit of science comes through the sacrifice of many people. My family back home in India -parents, sister, grand-parents -have had to patiently wait for the brief interludes when I go home. No words can do justice to this and the very many other pleasures they have surrendered over the years for my sake. Before physics attracted me, I was charmed by someone else; I am lucky to have married her. Long time friends, mentorsAjith and Subeesh -have played pivotal roles in my being able to engage in physics; I hope to repay this enormous debt, some day.It was a privilege to have learnt from a few great teachers during my formative years. Their vision of an indelible unity in nature continues to motivate my study of physics. vii AbstractThe precision measurement of position has a long-standing tradition in physics. Cavendish's verification of the universal law of gravitation using a torsion pendulum, Perrin's confirmation of the atomic hypothesis via the precise measurement of the Brownian motion, and, the verification of the mechanical effect of electromagnetic radiation, all belong to this classical heritage. Quantum mechanics posits that the measurement of position results in an uncertain momentum; an idea developed to full maturity within the ...

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Overwhelming Thermomechanical Motion with Microwave Radiation Pressure Shot Noise

Cited by 71 publications

References 33 publications

Near-Field Integration of a SiN Nanobeam and aSiO2Microcavity for Heisenberg-Limited Displacement Sensing

Near-Field Integration of a SiN Nanobeam and aSiO2Microcavity for Heisenberg-Limited Displacement Sensing

Measuring and imaging nanomechanical motion with laser light

Quantum Limits on Measurement and Control of a Mechanical Oscillator

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