Hyperﬁne transition induced by atomic motion above a paraﬃn-coated magnetic ﬁlm

Journal of Physics B Pub Date : 2023-10-10 DOI:10.1088/1361-6455/acfde5

Naota Sekiguchi, Hiroaki Usui, Atsushi Hatakeyama

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Abstract

Abstract We measured transitions between the hyperfine levels of the electronic ground state of potassium-39 atoms (transition frequency: 460 MHz) as the atoms moved through a periodic magneto-static field produced above the magnetic-stripe domains of a magnetic film. The period length of the magnetic field was 3.8 µ m. The atoms were incident to the field as an impinging beam with the most probable velocity of 550 m s −1 and experienced a peak oscillating field of 20 mT. Unwanted spin relaxation caused by the collisions of the atoms with the film surface was suppressed by the paraffin coating on the film. We observed increasing hyperfine transition probabilities as the frequency of the field oscillations experienced by the atoms increased from 0 to 140 MHz for the atomic velocity of 550 m s −1 , by changing the incident angle of the atomic beam with respect to the stripe domains. Numerical calculation of the time evolution of the hyperfine states revealed that the oscillating magnetic field experienced by the atoms induced the hyperfine transitions, and the main process was not a single-quantum transition but rather multi-quanta transitions.

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石蜡涂层磁膜上原子运动诱导的超精细跃迁

摘要:我们测量了钾-39原子的电子基态的超精细能级之间的跃迁(跃迁频率:460 MHz)，当原子通过磁性薄膜的磁条域上方产生的周期性静磁场时。磁场的周期长度为3.8µm，原子以最可能速度为550 ms−1的冲击束入射到磁场中，并经历了20 mT的峰值振荡场。由于原子与膜表面碰撞引起的自旋松弛被膜上的石蜡涂层抑制了。我们观察到，当原子速度为550 ms−1时，原子经历的场振荡频率从0增加到140 MHz，通过改变原子束相对于条纹域的入射角，超精细跃迁概率增加。超精细态时间演化的数值计算表明，原子所经历的振荡磁场诱发了超精细态的跃迁，且其主要过程不是单量子跃迁而是多量子跃迁。

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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Journal of Physics B

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