期刊
PHYSICAL REVIEW APPLIED
卷 18, 期 3, 页码 -出版社
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevApplied.18.034058
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资金
- JST OPERA [JPMJOP1841]
- KAKENHI [21H04653]
- Collaborative Research Program of ICR, Kyoto University [2021-114]
Exquisite sensitivities are a prominent advantage of quantum sensors. In this paper, a fitting-based algorithm with frequency-independent sensitivity is proposed to coherently measure low-frequency fields. The algorithm demonstrates a sensitivity of 9.4 nT Hz(-0.5) for frequencies below 0.6 kHz, showing its potential in various scenarios.
Exquisite sensitivities are a prominent advantage of quantum sensors. Ramsey sequences allow precise measurement of direct current fields, while Hahn-echo-like sequences measure alternating current fields. However, the latter are restrained for use with high-frequency fields (above approximately 1 kHz) due to finite coherence times, leaving less-sensitive noncoherent methods for the low-frequency range. In this paper, we propose to bridge the gap with a fitting-based algorithm with a frequency-independent sensitivity to coherently measure low-frequency fields. As the algorithm benefits from coherence-based measurements, its demonstration with a single nitrogen-vacancy center gives a sensitivity of 9.4 nT Hz(-0.5) for frequencies below about 0.6 kHz down to near-constant fields. To inspect the potential in various scenarios, we apply the algorithm at a background field of tens of nTs, and we measure low-frequency signals via synchronization.
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