Beating thermal noise in a dynamic signal measurement by a nanofabricated cavity optomechanical sensor

Wang, Mingkang; Perez-Morelo, Diego J.; Ramer, Georg; Pavlidis, Georges; Schwartz, Jeffrey J.; Yu, Liya E.; Ilic, Rob; Centrone, Andrea; Aksyuk, Vladimir A.

doi:10.1126/sciadv.adf7595

Sci. Adv.

2023

DOI: 10.1126/sciadv.adf7595

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Beating thermal noise in a dynamic signal measurement by a nanofabricated cavity optomechanical sensor

Mingkang Wang

Diego J. Perez-Morelo

Georg Ramer

et al.

Abstract: Thermal fluctuations often impose both fundamental and practical measurement limits on high-performance sensors, motivating the development of techniques that bypass the limitations imposed by thermal noise outside cryogenic environments. Here, we theoretically propose and experimentally demonstrate a measurement method that reduces the effective transducer temperature and improves the measurement precision of a dynamic impulse response signal. Thermal noise–limited, integrated cavity optomechanical atomic for… Show more

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2024

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Cited by 2 publications

References 43 publications

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Ultra‐Stable Phonon Laser Through Closed‐Loop Feedback Control for Optomechanical Sensing

Pan,

Yang,

Liu

et al. 2024

Laser & Photonics Reviews

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The resonant amplification of the optical and mechanical components in cavity optomechanical systems enhances the performance of sensing applications, which rely on precise frequency control and narrowed mechanical linewidth. This study proposes a direct closed‐loop feedback technique for a narrow linewidth phonon laser based on optomechanical self‐oscillation. By continuously pumping a mechanical resonator with a laser, a phonon laser is achieved with an oscillation frequency of 17.58 MHz, exhibiting a narrow linewidth of just 0.44 mHz and an effective mechanical Q of 4 × 1010, while preserving the linear frequency response. The oscillator phase is fed back to the pump laser, yielding a mechanical frequency stability of 7.2 × 10−11 and providing a real‐time output of direct current voltage corresponding to the oscillator frequency changes. The system's real‐time sensing capability is tested using fiber probes and polystyrene particles, demonstrating a performance approach to the theoretical resolution limit. This work opens new avenues for real‐time precision measurement technology and can be extended to different optomechanical systems.

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Ultra‐Stable Phonon Laser Through Closed‐Loop Feedback Control for Optomechanical Sensing

Pan,

Yang,

Liu

et al. 2024

Laser & Photonics Reviews

View full text Add to dashboard Cite

show abstract

Sequential hypothesis testing for continuously-monitored quantum systems

Gasbarri,

Bilkis,

Roda-Salichs

et al. 2024

Quantum

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We consider a quantum system that is being continuously monitored, giving rise to a measurement signal. From such a stream of data, information needs to be inferred about the underlying system's dynamics. Here we focus on hypothesis testing problems and put forward the usage of sequential strategies where the signal is analyzed in real time, allowing the experiment to be concluded as soon as the underlying hypothesis can be identified with a certified prescribed success probability. We analyze the performance of sequential tests by studying the stopping-time behavior, showing a considerable advantage over currently-used strategies based on a fixed predetermined measurement time.

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Beating thermal noise in a dynamic signal measurement by a nanofabricated cavity optomechanical sensor

Cited by 2 publications

References 43 publications

Ultra‐Stable Phonon Laser Through Closed‐Loop Feedback Control for Optomechanical Sensing

Ultra‐Stable Phonon Laser Through Closed‐Loop Feedback Control for Optomechanical Sensing

Sequential hypothesis testing for continuously-monitored quantum systems

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