R. Tang, R. Si, Zejie Fei, Xiaoxi Fu, Yuzhu Lu, T. Brage, Hongtao Liu, Chongyang Chen, C. Ning
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引用次数: 3
摘要
尽管激光冷却方法是一种成熟的获得超冷中性原子和原子阳离子的技术,但由于缺乏合适的电偶极子跃迁,迄今尚未应用于原子阴离子。经过十多年的努力,目前La$^-$是唯一有希望用于激光冷却的候选者。我们之前的工作[Tang et al., Phys.]Rev. Lett. 123, 203002(2019)]表明Th$^-$也是潜在的候选者。在这里,我们报告了实验和理论研究的结合,以确定Th$^-$中的相关跃迁频率,跃迁速率和分支比。确定了激光冷却跃迁的共振频率为$\nu/c$ = 4118.0 (10) cm$^{-1}$。跃迁速率计算为A=1.17x10^4 s$^{-1}$。到暗态的分支分数非常小,为1.47x10$^{-10}$,因此这代表了激光冷却的理想闭合循环。由于Th的核自旋为零,因此它是用来冷却潘宁阱中反质子的极好候选者。
Observation of electric-dipole transitions in the laser-cooling candidate
Th−
and its application for cooling antiprotons
Despite the fact that the laser cooling method is a well-established technique to obtain ultra-cold neutral atoms and atomic cations, it has so far never been applied to atomic anions due to the lack of suitable electric-dipole transitions. Efforts of more than a decade currently has La$^-$ as the only promising candidate for laser cooling. Our previous work [Tang et al., Phys. Rev. Lett. 123, 203002(2019)] showed that Th$^-$ is also a potential candidate. Here we report on a combination of experimental and theoretical studies to determine the relevant transition frequencies, transition rates, and branching ratios in Th$^-$. The resonant frequency of the laser cooling transition is determined to be $\nu/c$ = 4118.0 (10) cm$^{-1}$. The transition rate is calculated as A=1.17x10^4 s$^{-1}$. The branching fraction to dark states is very small, 1.47x10$^{-10}$, thus this represents an ideal closed cycle for laser cooling. Since Th has zero nuclear spin, it is an excellent candidate to be used to sympathetically cool antiprotons in a Penning trap.
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