Present Status of Spectroscopy of the Hyperfine Structure and Repolarization of Muonic Helium Atoms at J-PARC

IF 1.5 Q2 PHYSICS, MULTIDISCIPLINARY Physics Pub Date : 2024-06-12 DOI:10.3390/physics6020054

S. Fukumura, P. Strasser, Mahiro Fushihara, Yu Goto, Takashi Ino, R. Iwai, Sohtaro Kanda, Shiori Kawamura, M. Kitaguchi, Shoichiro Nishimura, Takayuki Oku, T. Okudaira, H. Shimizu, K. Shimomura, Hiroki Tada, H. A. Torii

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Abstract

The mass mμ− of the negative muon is one of the parameters of the elementary particle Standard Model and it allows us to verify the CPT (charge–parity–time) symmetry theorem by comparing mμ− value with the mass mμ+ of the positive muon. However, the experimental determination precision of mμ− is 3.1ppm, which is an order of magnitude lower than the determination precision of mμ+ at 120ppb. The authors aim to determine mμ− and the magnetic moment μμ− with a precision of O(10ppb) through spectroscopy of the hyperfine structure (HFS) of muonic helium-4 atom (4Heμ−e−) under high magnetic fields. He4μ−e− is an exotic atom where one of the two electrons of the He4 atom is replaced by a negative muon. To achieve the goal, it is necessary to determine the HFS of He4μ−e− with a precision of O(1ppb). This paper describes the determination procedure of the HFS of He4μ−e− in weak magnetic fields reported recently, and the work towards achieving the goal of higher precision measurement.

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J-PARC 的氦原子超细结构和再极化光谱学研究现状

负μ介子的质量mμ-是基本粒子标准模型的参数之一，通过比较mμ-值和正μ介子的质量mμ+，我们可以验证CPT（电荷-奇偶-时间）对称定理。然而，mμ-的实验测定精度为3.1ppm，比120ppb时mμ+的测定精度低了一个数量级。作者的目标是通过高磁场下μ介子氦-4 原子（4Heμ-e-）的超细结构（HFS）光谱测定 mμ- 和磁矩 μμ-，精度为 O(10ppb)。氦4μ-e是一种奇异的原子，其中氦4原子的两个电子之一被一个负μ介子取代。为实现这一目标，有必要测定 He4μ-e- 的 HFS，精度为 O(1ppb)。本文介绍了最近报道的弱磁场中 He4μ-e 的 HFS 测定过程，以及为实现更高精度测量目标所做的工作。

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