Approaching the standard quantum limit of mechanical torque sensing

Kim, P. H.; Hauer, Bradley; Doolin, C.; Souris, Fabien; Davis, J. P.

doi:10.1038/ncomms13165

Cited by 76 publications

(78 citation statements)

References 36 publications

(98 reference statements)

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“…We measure a record small torque of (1.2 ± 0.5) × 10 −27 Nm and achieve a record high rotational speed exceeding 5 GHz for a nanorotor. The measured torque sensitivity of our system at room temperature is several orders better than that of the state-of-the-art nanofabricated torque sensor at mK temperatures [6]. Our system will be suitable to detect the quantum vacuum friction [7][8][9][10].…”

mentioning

confidence: 86%

“…Great effort has been made to improve the torque detection sensitivity by nanofabrication and cryogenic cooling. The most sensitive nanofabricated torque sensor has achieved a remarkable sensitivity of 10 −24 Nm/ √Hz at millikelvin temperatures in a dilution refrigerator [6]. Here we dramatically improve the torque detection sensitivity by developing an ultrasensitive torque sensor with an optically levitated nanorotor in vacuum.…”

mentioning

confidence: 99%

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Ultrasensitive torque detection with an optically levitated nanorotor

Ahn¹,

Xu²,

Bang³

et al. 2020

Nat. Nanotechnol.

206

180

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Torque sensors such as the torsion balance enabled the first determination of the gravitational constant by Cavendish [1] and the discovery of Coulomb's law. Torque sensors are also widely used in studying small-scale magnetism [2,3], the Casimir effect [4], and other applications [5]. Great effort has been made to improve the torque detection sensitivity by nanofabrication and cryogenic cooling. The most sensitive nanofabricated torque sensor has achieved a remarkable sensitivity of 10 −24 Nm/ √Hz at millikelvin temperatures in a dilution refrigerator [6]. Here we dramatically improve the torque detection sensitivity by developing an ultrasensitive torque sensor with an optically levitated nanorotor in vacuum. We measure a torque as small as (1.2±0.5)×10 −27 Nm in 100 seconds at room temperature. Our system does not require complex nanofabrication or cryogenic cooling. Moreover, we drive a nanoparticle to rotate at a record high speed beyond 5 GHz (300 billion rpm). Our calculations show that this system will be able to detect the long-sought vacuum friction [7-10] near a surface under realistic conditions. The optically levitated nanorotor will also have applications in studying nanoscale magnetism [2,3] and quantum geometric phase [11].

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mentioning

confidence: 86%

mentioning

confidence: 99%

Ultrasensitive torque detection with an optically levitated nanorotor

Ahn¹,

Xu²,

Bang³

et al. 2020

Nat. Nanotechnol.

206

180

View full text Add to dashboard Cite

show abstract

“…1b ), is separated from the evanescent field of a whispering-gallery-mode (WGM) optical cavity by an 87 nm vacuum gap. A platform for the magnetic sample was designed near the end of the torsion arm, amplifying the magnetic actuation of the torsional resonator 18 , yet is sufficiently far from the evanescent field of the WGM such that its optical properties are unaffected ( Q opt = 5.3 × 10 4 ). On this platform we have deposited a ferromagnetic sample, which enables the mechanical motion to be driven, amplified, or dampened, by an alternating (ac) external magnetic field.…”

Section: Resultsmentioning

confidence: 99%

Magnetic actuation and feedback cooling of a cavity optomechanical torque sensor

et al. 2017

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Cavity optomechanics has demonstrated remarkable capabilities, such as measurement and control of mechanical motion at the quantum level. Yet many compelling applications of optomechanics—such as microwave-to-telecom wavelength conversion, quantum memories, materials studies, and sensing applications—require hybrid devices, where the optomechanical system is coupled to a separate, typically condensed matter, system. Here, we demonstrate such a hybrid optomechanical system, in which a mesoscopic ferromagnetic needle is integrated with an optomechanical torsional resonator. Using this system we quantitatively extract the magnetization of the needle, not known a priori, demonstrating the potential of this system for studies of nanomagnetism. Furthermore, we show that we can magnetically dampen its torsional mode from room-temperature to 11.6 K—improving its mechanical response time without sacrificing torque sensitivity. Future extensions will enable studies of high-frequency spin dynamics and broadband wavelength conversion via torque mixing.

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“…The feedback-cooled modal temperature as determined by fitting to the blue trace is T = 12 K. (Figures from Refs. [109,52], used with permission.) tal mode volume on the order of one cubic wavelength.…”

Section: Measurements With Photonic Crystal Cavity Readoutmentioning

confidence: 99%

Recent advances in mechanical torque studies of small-scale magnetism

Losby

Sauer

Freeman

2018

J. Phys. D: Appl. Phys.

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There is a storied scientific history in the role of mechanical instruments for the measurement of fundamental physical interactions. Among these include the detection of magnetic torques via a displacement of a compliant mechanical sensor as a result of angular momentum transfer. Modern nanofabrication methods have enabled the coupling of mechanical structures to single, miniature magnetic specimens. This has allowed for strikingly sensitive detection of magnetic hysteresis and other quasi-static effects, as well as spin resonances, in materials confined to nanoscale geometries. The extraordinary sensitivities achieved in mechanical transduction through recent breakthroughs in cavity optomechanics, where a high-finesse optical cavity is used for readout of motion, are now being harnessed for torque magnetometry. In this article, we review the recent progress in mechanical detection of magnetic torques, highlight current applications, and speculate on possible future developments in the technology and science. Guidelines for designing and implementing the measurements are also included. Acknowledgements 21 Appendix: Designer's guide 22 A feel for the numbers 22 Underlying scaling behaviour as a function of torque sensor/specimen linear size 22 Readout sensitivity 23 Low finesse interferometer 23 High finesse optical cavity 24 References 25 arXiv:1806.06288v1 [cond-mat.mes-hall]

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Approaching the standard quantum limit of mechanical torque sensing

Cited by 76 publications

References 36 publications

Ultrasensitive torque detection with an optically levitated nanorotor

Ultrasensitive torque detection with an optically levitated nanorotor

Magnetic actuation and feedback cooling of a cavity optomechanical torque sensor

Recent advances in mechanical torque studies of small-scale magnetism

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