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快速精确调节稳频点的远共振线激光稳频方法 被引量:1

Off-resonance laser frequency stabilization method for fast and accurate adjustment of frequency lock points
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摘要 原子磁强计、激光冷却等技术需要将激光频率稳定在远离原子跃迁频率几兆赫兹的大失谐处,法拉第旋光光谱稳频方法能够实现远共振线的大失谐处的稳频,但是存在稳频点调节不便的问题。在法拉第旋光光谱稳频方法的基础上进行改进,提出了一种快速精确调节稳频点的远共振线激光稳频方法,能够在几十至几百兆赫兹范围内对稳频点频率进行快速精确的调节。基于该方法使失谐为-6.2 GHz的稳频点精确频移130 MHz,并实现频率漂移3.3 MHz/h,波动均方根值0.6 MHz/h的激光频率稳定度,满足原子磁强计对失谐及频率稳定性的要求。另外,分析了温度对该稳频方法的影响,推导了预估稳频点频率的物理参数,并将温度调节和声光调制器(AOM)调节相结合,以更好地实现在远共振线大失谐处对激光频率的长期稳定和精确控制。 The atomic magnetometer and Raman cooling need to lock the frequency of the laser on the detuning of several gigahertz away from the resonance. The laser frequency stabilization technique in Faraday rotation spectroscopy can stabilize the laser frequency on the large detuning away from the resonance. But,in this method,changing the frequency lock points can be complex and has high latency. We present a far offresonance laser frequency stabilization method that can fast and accurately adjust the frequency lock points in the range of tens to hundreds of megahertz based on the Faraday rotation spectroscopy. Based on this method,the frequency lock point whose detuning is-6. 2 GHz is precisely shifted by 130 MHz,and we obtain a frequency drift of 3. 3 MHz/h and a root mean square fluctuation of 0. 6 MHz/h. This satisfies the detuning and frequency stability requirements of atomic magnetometer. In this paper,the influence of temperature on the frequency stabilization method is analyzed,the physical constant in the detuning equation is measured to estimate the frequency of the stabilization point,and the temperature regulation and acousto-optic modulator(AOM) regulation are combined to improve the long-term stable and precise control of the laser frequency on the large detuning of off-resonance.
作者 房子善 全伟 翟跃阳 FANG Zishan;QUAN Wei;ZHAI Yueyang(Science and Technology on Inertial Laboratory,Beijlng University of Aeronautics and Astronautics,Beijing 100083,China;Fundamental Science on Novel Inertial Instrument & Navigation System Technology Laboratory,Beijlng University of Aeronautics and Astronautics,Beijing 100083,China)
机构地区 北京航空航天大学惯性技术重点实验室 北京航空航天大学新型惯性仪表与导航系统技术国防重点学科实验室
出处 《北京航空航天大学学报》 EI CAS CSCD 北大核心 2018年第8期1727-1732,共6页 Journal of Beijing University of Aeronautics and Astronautics
基金 国家自然科学基金(61227902 61374210 61673041 61473268 61503353)~~
关键词 半导体激光器 激光稳频技术 激光光谱 原子光谱 法拉第旋光 diode laser laser frequency stabilization technology laser spectroscopy atomic spectroscopy Faraday rotation
分类号 V441 [航空宇航科学与技术—飞行器设计] O433.54 [机械工程—光学工程]
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北京航空航天大学学报
2018年 第8期

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