Atom-Light Hybrid Quantum Gyroscope

Yuan Wu; Jinxian Guo; Xiaotian Feng; L. Q. Chen; Chun Hua Yuan; Weiping Zhang

doi:10.1103/PhysRevApplied.14.064023

Atom-Light Hybrid Quantum Gyroscope

Yuan Wu, Jinxian Guo, Xiaotian Feng, L. Q. Chen, Chun Hua Yuan, Weiping Zhang

School of Physics and Electronic Science

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

15 Scopus citations

Abstract

An atom-light hybrid quantum gyroscope (ALHQG) is proposed due to its high rotation sensitivity. It consists of an optical Sagnac loop to couple rotation rate and an atomic ensemble as quantum beam splitter (recombiner) [QBS(C)] based on atomic Raman-amplification process to realize the splitting and recombination of the optical wave and the atomic spin wave. The rotation sensitivity can be enhanced by the quantum correlation between Sagnac loop and QBS(C). The optimal working condition is investigated to achieve the best sensitivity. The numerical results show that the rotation sensitivity can beat the standard quantum limit (SQL) in ideal condition. Even in the presence of the attenuation under practical condition, the best sensitivity of the ALHQG can still beat the SQL and is better than that of a classical fiber optic gyroscope. Such an ALHQG could be practically applied for modern inertial navigation system.

Original language	English
Article number	064023
Journal	Physical Review Applied
Volume	14
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevApplied.14.064023
State	Published - 8 Dec 2020

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10.1103/PhysRevApplied.14.064023

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title = "Atom-Light Hybrid Quantum Gyroscope",

abstract = "An atom-light hybrid quantum gyroscope (ALHQG) is proposed due to its high rotation sensitivity. It consists of an optical Sagnac loop to couple rotation rate and an atomic ensemble as quantum beam splitter (recombiner) [QBS(C)] based on atomic Raman-amplification process to realize the splitting and recombination of the optical wave and the atomic spin wave. The rotation sensitivity can be enhanced by the quantum correlation between Sagnac loop and QBS(C). The optimal working condition is investigated to achieve the best sensitivity. The numerical results show that the rotation sensitivity can beat the standard quantum limit (SQL) in ideal condition. Even in the presence of the attenuation under practical condition, the best sensitivity of the ALHQG can still beat the SQL and is better than that of a classical fiber optic gyroscope. Such an ALHQG could be practically applied for modern inertial navigation system.",

author = "Yuan Wu and Jinxian Guo and Xiaotian Feng and Chen, \{L. Q.\} and Yuan, \{Chun Hua\} and Weiping Zhang",

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doi = "10.1103/PhysRevApplied.14.064023",

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AU - Wu, Yuan

AU - Guo, Jinxian

AU - Feng, Xiaotian

AU - Chen, L. Q.

AU - Yuan, Chun Hua

AU - Zhang, Weiping

PY - 2020/12/8

Y1 - 2020/12/8

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AB - An atom-light hybrid quantum gyroscope (ALHQG) is proposed due to its high rotation sensitivity. It consists of an optical Sagnac loop to couple rotation rate and an atomic ensemble as quantum beam splitter (recombiner) [QBS(C)] based on atomic Raman-amplification process to realize the splitting and recombination of the optical wave and the atomic spin wave. The rotation sensitivity can be enhanced by the quantum correlation between Sagnac loop and QBS(C). The optimal working condition is investigated to achieve the best sensitivity. The numerical results show that the rotation sensitivity can beat the standard quantum limit (SQL) in ideal condition. Even in the presence of the attenuation under practical condition, the best sensitivity of the ALHQG can still beat the SQL and is better than that of a classical fiber optic gyroscope. Such an ALHQG could be practically applied for modern inertial navigation system.

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Atom-Light Hybrid Quantum Gyroscope

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