Enhanced Quantum Metrology with Non-Phase-Covariant Noise

Jia Xin Peng; Baiqiang Zhu; Weiping Zhang; Keye Zhang

doi:10.1103/PhysRevLett.133.090801

Enhanced Quantum Metrology with Non-Phase-Covariant Noise

Jia Xin Peng, Baiqiang Zhu, Weiping Zhang^*, Keye Zhang^*

^*Corresponding author for this work

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

5 Scopus citations

Abstract

The detrimental impact of noise on sensing performance in quantum metrology has been widely recognized by researchers in the field. However, there are no explicit fundamental laws of physics stating that noise invariably weakens quantum metrology. We reveal that phase-covariant noise either degrades or remains neutral to sensing precision, whereas non-phase-covariant noise can potentially enhance parameter estimation, surpassing even the ultimate precision limit achievable in the absence of noise. This implies that a non-Hermitian quantum sensor may outperform its Hermitian counterpart in terms of sensing performance. To illustrate and validate our theory, we present several paradigmatic examples of magnetic field metrology.

Original language	English
Article number	090801
Journal	Physical Review Letters
Volume	133
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.133.090801
State	Published - 30 Aug 2024
Externally published	Yes

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10.1103/PhysRevLett.133.090801

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title = "Enhanced Quantum Metrology with Non-Phase-Covariant Noise",

abstract = "The detrimental impact of noise on sensing performance in quantum metrology has been widely recognized by researchers in the field. However, there are no explicit fundamental laws of physics stating that noise invariably weakens quantum metrology. We reveal that phase-covariant noise either degrades or remains neutral to sensing precision, whereas non-phase-covariant noise can potentially enhance parameter estimation, surpassing even the ultimate precision limit achievable in the absence of noise. This implies that a non-Hermitian quantum sensor may outperform its Hermitian counterpart in terms of sensing performance. To illustrate and validate our theory, we present several paradigmatic examples of magnetic field metrology.",

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AU - Peng, Jia Xin

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AU - Zhang, Weiping

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PY - 2024/8/30

Y1 - 2024/8/30

N2 - The detrimental impact of noise on sensing performance in quantum metrology has been widely recognized by researchers in the field. However, there are no explicit fundamental laws of physics stating that noise invariably weakens quantum metrology. We reveal that phase-covariant noise either degrades or remains neutral to sensing precision, whereas non-phase-covariant noise can potentially enhance parameter estimation, surpassing even the ultimate precision limit achievable in the absence of noise. This implies that a non-Hermitian quantum sensor may outperform its Hermitian counterpart in terms of sensing performance. To illustrate and validate our theory, we present several paradigmatic examples of magnetic field metrology.

AB - The detrimental impact of noise on sensing performance in quantum metrology has been widely recognized by researchers in the field. However, there are no explicit fundamental laws of physics stating that noise invariably weakens quantum metrology. We reveal that phase-covariant noise either degrades or remains neutral to sensing precision, whereas non-phase-covariant noise can potentially enhance parameter estimation, surpassing even the ultimate precision limit achievable in the absence of noise. This implies that a non-Hermitian quantum sensor may outperform its Hermitian counterpart in terms of sensing performance. To illustrate and validate our theory, we present several paradigmatic examples of magnetic field metrology.

UR - https://www.scopus.com/pages/publications/85202865155

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Enhanced Quantum Metrology with Non-Phase-Covariant Noise

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