非线性磁光旋转原子磁力计原子极化矩的识别与操纵

IF 4.4 Q1 OPTICS Advanced quantum technologies Pub Date : 2024-07-19 DOI:10.1002/qute.202400063
Yanchao Chai, Liwei Jiang, Jiali Liu, Xin Zhao, Mengnan Tian, Zhenglong Lu, Xusheng Lei, Zhuo Wang, Wei Quan
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引用次数: 0

摘要

极化矩在非线性磁光旋转(NMOR)原子磁强计的磁场测量中起着至关重要的作用。然而,在带有缓冲气体的碱蒸气池中,区分每种极化力矩并评估其对磁共振响应信号的影响具有挑战性。为了解决这个问题,我们提出了一种通过磁共振响应信号的频率偏移来识别不同极化矩的方法。该方法确定了每种极化矩的比例,并证明磁共振响应信号受十六极矩的影响,导致频率偏移和信号振幅减小。为了减轻这种影响,研究人员研究了一种通过翻转泵浦光的相位来操纵偏振矩的方法。最终,在磁屏蔽桶内的模拟地磁环境中,响应振幅提高了 15.19%。本文介绍的理论和方法为研究带有缓冲气体的碱蒸气电池中的偏振矩提供了有力支持,从而有可能提高 NMOR 原子磁强计的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Identification and Manipulation of Atomic Polarization Moments for Nonlinear Magneto-Optical Rotation Atomic Magnetometers

Polarization moments play a crucial role in measuring magnetic fields for nonlinear magneto-optical rotation (NMOR) atomic magnetometers. However, it is challenging to distinguish between each polarization moment and evaluate its effect on the magnetic resonance response signal in an alkali vapor cell with buffer gas. To address this issue, a method is proposed to identify different polarization moments through the frequency shift of the magnetic resonance response signal. The proportion of each polarization moment is determined, and it is demonstrated that the magnetic resonance response signal is affected by the hexadecapole moment, resulting in a frequency shift and a decrease in signal amplitude. To mitigate this effect, an approach is investigated to manipulate the polarization moments by flipping the phase of the pump light. Ultimately, a 15.19% increase in response amplitude is achieved in the simulated geomagnetic environment within the magnetic shield barrel. The theory and method presented here provide strong support for the study of the polarization moments in an alkali vapor cell with buffer gas, which potentially enhance the performance of NMOR atomic magnetometers.

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