Valuev Igor A, Colò Gianluca, Roca-Maza Xavier, Keitel Christoph H, Oreshkina Natalia S
Max-Planck-Institut für Kernphysik, Saupfercheckweg 1, 69117 Heidelberg, Germany.
Dipartimento di Fisica, Università degli Studi di Milano, via Celoria 16, I-20133 Milano, Italy.
Phys Rev Lett. 2022 May 20;128(20):203001. doi: 10.1103/PhysRevLett.128.203001.
A long-standing problem of fine-structure anomalies in muonic atoms is revisited by considering the splittings Δ2p=E_{2p_{3/2}}-E_{2p_{1/2}} in muonic ^{90}Zr, ^{120}Sn, and ^{208}Pb and Δ3p=E_{3p_{3/2}}-E_{3p_{1/2}} in muonic ^{208}Pb. State-of-the-art techniques from both nuclear and atomic physics are brought together in order to perform the most comprehensive to date calculations of nuclear-polarization energy shifts. Barring the more subtle case of μ-^{208}Pb, the results suggest that the dominant calculation uncertainty is much smaller than the persisting discrepancies between theory and experiment. We conclude that the resolution to the anomalies is likely to be rooted in refined quantum-electrodynamics corrections or even some other previously unaccounted-for contributions.
通过考虑μ子化的(^{90}Zr)、(^{120}Sn)和(^{208}Pb)中的分裂(\Delta2p = E_{2p_{3/2}} - E_{2p_{1/2}})以及μ子化的(^{208}Pb)中的(\Delta3p = E_{3p_{3/2}} - E_{3p_{1/2}}),重新审视了μ子原子中精细结构异常这一长期存在的问题。核物理和原子物理的最新技术被结合起来,以便进行迄今为止最全面的核极化能移计算。除了μ子化的(^{208}Pb)这种更微妙的情况外,结果表明主要的计算不确定性远小于理论与实验之间持续存在的差异。我们得出结论,异常现象的解决方案可能源于精细的量子电动力学修正,甚至是一些其他先前未考虑的贡献。
