Classical Dynamics of Muonic-Electronic Helium and Heliumlike Ions: The Allowance for the Eccentricity of the Muon and Nucleus Orbits

N. Kryukov, E. Oks
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Abstract

In the previous paper by one of us (hereafter paper I), the author considered Rydberg states of the muonic-electronic helium atom or helium-like ion and used the fact that the muon motion occurs much more rapidly than the electron motion. Assuming that the muon and nucleus orbits are circular, he applied the analytical method based on separating rapid and slow subsystems. He showed that the electron moves in an effective potential that is mathematically equivalent to the potential of a satellite orbiting an oblate planet like the Earth. He also showed that the “unperturbed” elliptical orbit of the electron engages in two precessions simultaneously: the precession of the electron orbit in the plane of the orbit and the precession of the orbital plane of the electron around the axis perpendicular to the plane of the muon and nuclear orbits. The problem remained whether or not the allowance for the ellipticity of the orbit could significantly change the results. In the present paper, we address this problem: we study how the allowance for a relatively low eccentricity e of the muon and nucleus orbits affects the motion of the electron. We derive an additional, e-dependent term in the effective potential for the motion of the electron. We show analytically that in the particular case of the planar geometry (where the electron orbit is in the plane of the muon and nucleus orbits), it leads to an additional contribution to the frequency of the precession of the electron orbit. We demonstrate that this additional, e-depen- dent contribution to the precession frequency of the electron orbit can reach the same order of magnitude as the primary, e-independent contribution to the precession frequency. Therefore, the results of our paper seem to be important not only qualitatively, but also quantitatively.
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介子电子氦离子和类氦离子的经典动力学:对介子和原子核轨道偏心率的允许
在我们之前的一篇论文(下文为第1篇)中,作者考虑了介子电子氦原子或类氦离子的里德堡态,并利用了介子运动比电子运动快得多的事实。假设介子和原子核的轨道是圆形的,他采用了基于分离快、慢子系统的分析方法。他证明了电子以有效势运动,这个势在数学上相当于一颗绕着像地球这样的扁行星运行的卫星的势。他还表明,电子的“无扰动”椭圆轨道同时有两种进动:电子轨道在轨道平面上的进动,以及电子轨道平面围绕垂直于介子和核轨道平面的轴的进动。问题仍然是考虑轨道的椭圆性是否会显著改变结果。在本文中,我们解决了这个问题:我们研究了介子和原子核轨道相对较低的偏心率e是如何影响电子的运动的。我们在电子运动的有效势中导出了一个附加的、与电子有关的项。我们分析地表明,在平面几何的特殊情况下(电子轨道在介子和原子核轨道的平面上),它会导致电子轨道进动频率的额外贡献。我们证明,这种额外的、与电子轨道的进动频率相关的贡献可以达到与主要的、与电子轨道无关的进动频率相同的数量级。因此,我们论文的结果似乎不仅在定性上很重要,而且在定量上也很重要。
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