High-precision gravimeter based on a nano-mechanical resonator hybrid with an electron spin

Xing Yan Chen; Zhang Qi Yin

doi:10.1364/OE.26.031577

High-precision gravimeter based on a nano-mechanical resonator hybrid with an electron spin

Xing Yan Chen, Zhang Qi Yin^*

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

19 引用（Scopus）

摘要

We show that the gravitational acceleration can be measured with the matter-wave Ramsey interferometry, by using a nitrogen-vacancy center coupled to a nano-mechanical resonator. We propose two experimental methods to realize the similar Hamiltonian, by using either a cantilever resonator or a trapped nanoparticle. The scheme is robust against the thermal noise, and could be realized at the temperature much higher than the quantum regime. The effects of decoherence on the interferometry fringe visibility is calculated, considering both the mechanical motional decay and dephasing of the nitrogen-vacancy center. In addition, we demonstrate that under the various sources of random and systematic noises, our gravimeter can be made on-chip and achieve a high measurement precision. Under experimental feasible parameters, the proposed gravimeter could achieve 10⁻¹⁰ relative precision.

源语言	英语
页（从-至）	31577-31588
页数	12
期刊	Optics Express
卷	26
期	24
DOI	https://doi.org/10.1364/OE.26.031577
出版状态	已出版 - 26 11月 2018
已对外发布	是

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Chen, X. Y., & Yin, Z. Q. (2018). High-precision gravimeter based on a nano-mechanical resonator hybrid with an electron spin. Optics Express, 26(24), 31577-31588. https://doi.org/10.1364/OE.26.031577

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title = "High-precision gravimeter based on a nano-mechanical resonator hybrid with an electron spin",

abstract = "We show that the gravitational acceleration can be measured with the matter-wave Ramsey interferometry, by using a nitrogen-vacancy center coupled to a nano-mechanical resonator. We propose two experimental methods to realize the similar Hamiltonian, by using either a cantilever resonator or a trapped nanoparticle. The scheme is robust against the thermal noise, and could be realized at the temperature much higher than the quantum regime. The effects of decoherence on the interferometry fringe visibility is calculated, considering both the mechanical motional decay and dephasing of the nitrogen-vacancy center. In addition, we demonstrate that under the various sources of random and systematic noises, our gravimeter can be made on-chip and achieve a high measurement precision. Under experimental feasible parameters, the proposed gravimeter could achieve 10−10 relative precision.",

author = "Chen, {Xing Yan} and Yin, {Zhang Qi}",

note = "Publisher Copyright: {\textcopyright} 2018 Optical Society of America under the terms of the OSA Open Access Publishing Agreement.",

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doi = "10.1364/OE.26.031577",

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N2 - We show that the gravitational acceleration can be measured with the matter-wave Ramsey interferometry, by using a nitrogen-vacancy center coupled to a nano-mechanical resonator. We propose two experimental methods to realize the similar Hamiltonian, by using either a cantilever resonator or a trapped nanoparticle. The scheme is robust against the thermal noise, and could be realized at the temperature much higher than the quantum regime. The effects of decoherence on the interferometry fringe visibility is calculated, considering both the mechanical motional decay and dephasing of the nitrogen-vacancy center. In addition, we demonstrate that under the various sources of random and systematic noises, our gravimeter can be made on-chip and achieve a high measurement precision. Under experimental feasible parameters, the proposed gravimeter could achieve 10−10 relative precision.

AB - We show that the gravitational acceleration can be measured with the matter-wave Ramsey interferometry, by using a nitrogen-vacancy center coupled to a nano-mechanical resonator. We propose two experimental methods to realize the similar Hamiltonian, by using either a cantilever resonator or a trapped nanoparticle. The scheme is robust against the thermal noise, and could be realized at the temperature much higher than the quantum regime. The effects of decoherence on the interferometry fringe visibility is calculated, considering both the mechanical motional decay and dephasing of the nitrogen-vacancy center. In addition, we demonstrate that under the various sources of random and systematic noises, our gravimeter can be made on-chip and achieve a high measurement precision. Under experimental feasible parameters, the proposed gravimeter could achieve 10−10 relative precision.

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High-precision gravimeter based on a nano-mechanical resonator hybrid with an electron spin

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