Self-Driven Hybrid Atomic Spin Oscillator

Erwei Li; Qianjin Ma; Guobin Liu; Peter Yun; Shougang Zhang

doi:10.1103/PhysRevApplied.20.014029

Self-Driven Hybrid Atomic Spin Oscillator

Erwei Li, Qianjin Ma, Guobin Liu, Peter Yun, Shougang Zhang

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

2 Scopus citations

Abstract

A self-driven hybrid atomic spin oscillator is demonstrated in theory and experiment with a vapor Rb-Xe dual-spin system. The raw signal of Rb spin oscillation is amplified, phase-shifted, and sent back to drive the Xe spins coherently. By fine-tuning the driving-field strength and phase, a self-sustaining spin-oscillation signal with zero frequency shift is obtained. The effective coherence time is infinitely prolonged beyond the intrinsic coherence time of Xe spins, forming a hybrid atomic spin oscillator. Spectral analysis indicates that a frequency resolution of 13.1 nHz is achieved, increasing the detection sensitivity for a magnetic field. Allan-deviation analysis shows that the spin oscillator can operate in continuous-wave mode like a spin maser. The prototype spin oscillator can be easily incorporated into other hybrid spin systems and can increase the detection sensitivity of alkali-metal-noble-gas comagnetometers.

Original language	English
Article number	014029
Journal	Physical Review Applied
Volume	20
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevApplied.20.014029
State	Published - 1 Jul 2023
Externally published	Yes

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevApplied.20.014029

Cite this

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abstract = "A self-driven hybrid atomic spin oscillator is demonstrated in theory and experiment with a vapor Rb-Xe dual-spin system. The raw signal of Rb spin oscillation is amplified, phase-shifted, and sent back to drive the Xe spins coherently. By fine-tuning the driving-field strength and phase, a self-sustaining spin-oscillation signal with zero frequency shift is obtained. The effective coherence time is infinitely prolonged beyond the intrinsic coherence time of Xe spins, forming a hybrid atomic spin oscillator. Spectral analysis indicates that a frequency resolution of 13.1 nHz is achieved, increasing the detection sensitivity for a magnetic field. Allan-deviation analysis shows that the spin oscillator can operate in continuous-wave mode like a spin maser. The prototype spin oscillator can be easily incorporated into other hybrid spin systems and can increase the detection sensitivity of alkali-metal-noble-gas comagnetometers.",

author = "Erwei Li and Qianjin Ma and Guobin Liu and Peter Yun and Shougang Zhang",

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T1 - Self-Driven Hybrid Atomic Spin Oscillator

AU - Li, Erwei

AU - Ma, Qianjin

AU - Liu, Guobin

AU - Yun, Peter

AU - Zhang, Shougang

PY - 2023/7/1

Y1 - 2023/7/1

N2 - A self-driven hybrid atomic spin oscillator is demonstrated in theory and experiment with a vapor Rb-Xe dual-spin system. The raw signal of Rb spin oscillation is amplified, phase-shifted, and sent back to drive the Xe spins coherently. By fine-tuning the driving-field strength and phase, a self-sustaining spin-oscillation signal with zero frequency shift is obtained. The effective coherence time is infinitely prolonged beyond the intrinsic coherence time of Xe spins, forming a hybrid atomic spin oscillator. Spectral analysis indicates that a frequency resolution of 13.1 nHz is achieved, increasing the detection sensitivity for a magnetic field. Allan-deviation analysis shows that the spin oscillator can operate in continuous-wave mode like a spin maser. The prototype spin oscillator can be easily incorporated into other hybrid spin systems and can increase the detection sensitivity of alkali-metal-noble-gas comagnetometers.

AB - A self-driven hybrid atomic spin oscillator is demonstrated in theory and experiment with a vapor Rb-Xe dual-spin system. The raw signal of Rb spin oscillation is amplified, phase-shifted, and sent back to drive the Xe spins coherently. By fine-tuning the driving-field strength and phase, a self-sustaining spin-oscillation signal with zero frequency shift is obtained. The effective coherence time is infinitely prolonged beyond the intrinsic coherence time of Xe spins, forming a hybrid atomic spin oscillator. Spectral analysis indicates that a frequency resolution of 13.1 nHz is achieved, increasing the detection sensitivity for a magnetic field. Allan-deviation analysis shows that the spin oscillator can operate in continuous-wave mode like a spin maser. The prototype spin oscillator can be easily incorporated into other hybrid spin systems and can increase the detection sensitivity of alkali-metal-noble-gas comagnetometers.

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Self-Driven Hybrid Atomic Spin Oscillator

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