Mechanical Dissipation below 1 μhz with a Cryogenic Diamagnetic Levitated Micro-Oscillator

Yingchun Leng; Rui Li; Xi Kong; Han Xie; Di Zheng; Peiran Yin; Fang Xiong; Tong Wu; Chang Kui Duan; Youwei Du; Zhang Qi Yin; Pu Huang; Jiangfeng Du

doi:10.1103/PhysRevApplied.15.024061

Mechanical Dissipation below 1 μhz with a Cryogenic Diamagnetic Levitated Micro-Oscillator

Yingchun Leng, Rui Li, Xi Kong, Han Xie, Di Zheng, Peiran Yin, Fang Xiong, Tong Wu, Chang Kui Duan, Youwei Du, Zhang Qi Yin, Pu Huang^*, Jiangfeng Du^*

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

28 Citations (Scopus)

Abstract

Ultralow-dissipation mechanical systems play an important role in metrology and exploring macroscopic quantum phenomena. Here we report a diamagnetic levitated micromechanical oscillator operating at 3 K with measured dissipation down to 0.59μHz and a quality factor up to 2×107. This mechanical system achieves the lowest dissipation among the state-of-the-art microscale and nanoscale mechanical systems reported to date, with orders-of-magnitude reduction over other systems based on different principles. The cryogenic diamagnetic levitated oscillator is applicable on a wide range of mass, making it a good candidate system for ultrasensitive measurements of both force and acceleration. By virtue of the strong magnetic gradient, this system is potentially capable of studying quantum spin mechanics.

Original language	English
Article number	024061
Journal	Physical Review Applied
Volume	15
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevApplied.15.024061
Publication status	Published - Feb 2021

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title = "Mechanical Dissipation below 1 μhz with a Cryogenic Diamagnetic Levitated Micro-Oscillator",

abstract = "Ultralow-dissipation mechanical systems play an important role in metrology and exploring macroscopic quantum phenomena. Here we report a diamagnetic levitated micromechanical oscillator operating at 3 K with measured dissipation down to 0.59μHz and a quality factor up to 2×107. This mechanical system achieves the lowest dissipation among the state-of-the-art microscale and nanoscale mechanical systems reported to date, with orders-of-magnitude reduction over other systems based on different principles. The cryogenic diamagnetic levitated oscillator is applicable on a wide range of mass, making it a good candidate system for ultrasensitive measurements of both force and acceleration. By virtue of the strong magnetic gradient, this system is potentially capable of studying quantum spin mechanics.",

author = "Yingchun Leng and Rui Li and Xi Kong and Han Xie and Di Zheng and Peiran Yin and Fang Xiong and Tong Wu and Duan, \{Chang Kui\} and Youwei Du and Yin, \{Zhang Qi\} and Pu Huang and Jiangfeng Du",

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doi = "10.1103/PhysRevApplied.15.024061",

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T1 - Mechanical Dissipation below 1 μhz with a Cryogenic Diamagnetic Levitated Micro-Oscillator

AU - Leng, Yingchun

AU - Li, Rui

AU - Kong, Xi

AU - Xie, Han

AU - Zheng, Di

AU - Yin, Peiran

AU - Xiong, Fang

AU - Wu, Tong

AU - Duan, Chang Kui

AU - Du, Youwei

AU - Yin, Zhang Qi

AU - Huang, Pu

AU - Du, Jiangfeng

PY - 2021/2

Y1 - 2021/2

N2 - Ultralow-dissipation mechanical systems play an important role in metrology and exploring macroscopic quantum phenomena. Here we report a diamagnetic levitated micromechanical oscillator operating at 3 K with measured dissipation down to 0.59μHz and a quality factor up to 2×107. This mechanical system achieves the lowest dissipation among the state-of-the-art microscale and nanoscale mechanical systems reported to date, with orders-of-magnitude reduction over other systems based on different principles. The cryogenic diamagnetic levitated oscillator is applicable on a wide range of mass, making it a good candidate system for ultrasensitive measurements of both force and acceleration. By virtue of the strong magnetic gradient, this system is potentially capable of studying quantum spin mechanics.

AB - Ultralow-dissipation mechanical systems play an important role in metrology and exploring macroscopic quantum phenomena. Here we report a diamagnetic levitated micromechanical oscillator operating at 3 K with measured dissipation down to 0.59μHz and a quality factor up to 2×107. This mechanical system achieves the lowest dissipation among the state-of-the-art microscale and nanoscale mechanical systems reported to date, with orders-of-magnitude reduction over other systems based on different principles. The cryogenic diamagnetic levitated oscillator is applicable on a wide range of mass, making it a good candidate system for ultrasensitive measurements of both force and acceleration. By virtue of the strong magnetic gradient, this system is potentially capable of studying quantum spin mechanics.

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U2 - 10.1103/PhysRevApplied.15.024061

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Mechanical Dissipation below 1 μhz with a Cryogenic Diamagnetic Levitated Micro-Oscillator

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