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Hauptverfasser: Zhuang, Min, Chen, Sijie, Huang, Jiahao, Lee, Chaohong
Format: Preprint
Veröffentlicht: 2023
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Online-Zugang:https://arxiv.org/abs/2308.02102
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author Zhuang, Min
Chen, Sijie
Huang, Jiahao
Lee, Chaohong
author_facet Zhuang, Min
Chen, Sijie
Huang, Jiahao
Lee, Chaohong
contents Precision measurement of magnetic fields is an important goal for fundamental science and practical sensing technology. Sensitive detection of a vector magnetic field is a crucial issue in quantum magnetometry, it remains a challenge to estimate a vector DC magnetic field with high efficiency and high precision. Here, we propose a general protocol for quantum vector DC magnetometry via selective phase accumulation of both non-entangled and entangled quantum probes. Based upon the Ramsey interferometry, our protocol may achieve selective phase accumulation of only one magnetic field component by inserting well-designed pulse sequence. In the parallel scheme, three parallel quantum interferometries are utilized to estimate three magnetic field components independently.In the sequential scheme, by applying a pulse sequence along different directions, three magnetic field components can be estimated simultaneously via only one quantum interferometry. In particular, if the input state is an entangled state such as the Greenberger-Horne-Zeilinger state, the measurement precisions of all three components may approach the Heisenberg limit. Our study not only develops a general protocol for measuring vector magnetic fields via quantum probes, but also provides a feasible way to achieve Heisenberg-limited multi-parameter estimation via many-body quantum entanglement.
format Preprint
id arxiv_https___arxiv_org_abs_2308_02102
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Quantum Vector DC Magnetometry via Selective Phase Accumulation
Zhuang, Min
Chen, Sijie
Huang, Jiahao
Lee, Chaohong
Quantum Physics
Precision measurement of magnetic fields is an important goal for fundamental science and practical sensing technology. Sensitive detection of a vector magnetic field is a crucial issue in quantum magnetometry, it remains a challenge to estimate a vector DC magnetic field with high efficiency and high precision. Here, we propose a general protocol for quantum vector DC magnetometry via selective phase accumulation of both non-entangled and entangled quantum probes. Based upon the Ramsey interferometry, our protocol may achieve selective phase accumulation of only one magnetic field component by inserting well-designed pulse sequence. In the parallel scheme, three parallel quantum interferometries are utilized to estimate three magnetic field components independently.In the sequential scheme, by applying a pulse sequence along different directions, three magnetic field components can be estimated simultaneously via only one quantum interferometry. In particular, if the input state is an entangled state such as the Greenberger-Horne-Zeilinger state, the measurement precisions of all three components may approach the Heisenberg limit. Our study not only develops a general protocol for measuring vector magnetic fields via quantum probes, but also provides a feasible way to achieve Heisenberg-limited multi-parameter estimation via many-body quantum entanglement.
title Quantum Vector DC Magnetometry via Selective Phase Accumulation
topic Quantum Physics
url https://arxiv.org/abs/2308.02102