Investigating Muonic Hydrogen Atom Energy Spectrum Using Perturbation Theory in Lowest Order

Firew Meka
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引用次数: 3

Abstract

This work presents a quantum mechanical calculation of corrections in energy levels of muonic hydrogen atom using a potential due to finite size proton. Muonic hydrogen (μ-p) is an exotic atom in which the muon (μ − ) replaces the electron "orbiting around" the proton in normal atomic hydrogen. Corrections in energy levels of Muonic hydrogen atom are calculated using a potential due to finite size proton. This Thesis analyzes the implications of Muonic hydrogenic atoms compared to standard hydrogenic atoms. These calculations are performed with Schrodinger wave functions with Coulomb potential using perturbation theory. The finite size of proton gives values of Lamb shift higher than that of point charge. The fine structure correction is very small compared to the Lamb shift values of Muonic hydrogen as we can see from the literature review. Therefore, as we have seen through all the above calculation of 1s, 2s and 2p, the application of perturbation theory has shown us that the energy correction is very small at each state. So the perturbation at higher order become small and small compared to the zero order at each state and even it can be ignored for higher orders. From this we can say that the interaction of electron with proton at higher state will be low which justifies that proton is not a large spherical shaped but it has finite size. Keywords: coulomb potential; Point proton; Finite size proton; muonic hydrogen atom; Energy levels corrections;  Lamb shift. DOI : 10.7176/APTA/83-02 Publication date: February 29 th 2020
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用最低阶微扰理论研究介子氢原子能谱
本文提出了利用有限尺寸质子的势对介子氢原子能级修正的量子力学计算。μ子氢(μ-p)是一种外来原子,其中μ子(μ−)取代了正常氢原子中“围绕”质子运行的电子。利用有限尺寸质子的势计算了介子氢原子能级的修正。本文分析了介子氢原子与标准氢原子的区别。这些计算是用带有库仑势的薛定谔波函数用微扰理论进行的。质子的有限尺寸使得兰姆位移值高于点电荷的兰姆位移值。从文献综述中可以看出,与μ子氢的Lamb位移值相比,其精细结构修正非常小。因此,正如我们通过以上对1s、2s和2p的计算所看到的,微扰理论的应用表明,在每个状态下的能量修正是非常小的。所以高阶的摄动在每个状态下都比零阶变得越来越小,甚至在高阶时也可以忽略。由此可知,质子在高能级时电子与质子的相互作用较小,这说明质子不是大的球形,而是有限的大小。关键词:库仑势;点质子;有限尺寸质子;介子氢原子;能级修正;兰姆移位。DOI: 10.7176/APTA/83-02出版日期:2020年2月29日
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