History and Some Aspects of the Lamb Shift

Maclay, G. Jordan

doi:10.3390/physics2020008

Cited by 10 publications

(23 citation statements)

References 110 publications

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“…The simple distribution (1) gives the correct analytical behavior of the electronic wavefunctions at r = 0 and has been used in many early analyses. These expansions are also useful for a general understanding of the effects involved [32].…”

Section: Methodology 21 Nuclear Potential and Wavefunctionmentioning

confidence: 99%

“…The hydrogen atom is the fundamental two-body system and perhaps the most important tool of atomic physics and the challenge is to calculate its properties to the highest accuracy possible. The study of the hydrogen atom has been at the heart of the development of modern physics [1]. The hydrogen atom has been the testing ground for theoretical atomic physics for over a hundred years.…”

Section: Introductionmentioning

confidence: 99%

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The Analytical Modeling of Nuclear Size Effect on Relativistic Electron in Hydrogen Atom

Adamu¹,

Hassan²,

Ahmad³

et al. 2020

NIPES

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The effects of relativistic motion, the spin-orbit interaction and Zitterbewegung of an electron, which are of the same order of magnitude, defined the fine structure correction to hydrogen spectra. In this work, perturbation theory, as an approximation method is applied to examine the effects of finite sized of atomic nucleus on relativistic motion of electron in hydrogen atom. The nuclear finite corrections to 1s, 2s, 3s, 4s and 5s energy states in hydrogen atom due to the finite size of nucleus were computed and the results showed that the nuclear size effects, which is of order of 10 -6 eV, depends on the size, A(N, Z) of the nucleus and energy states, n of relativistic electron. This suggested that the nuclear size is more effective on relativistic electron in the lower energy levels of heavy nuclei, as the effect varied directly with the nuclear size and inversely with the electron states, n. Thus, the finite size of atomic nucleus has an impact on relativistic motion of an electron. Moreover, a simple model was developed to predict the energy level variation as a function of the size of the nucleus. Therefore, this study justifies the effects of nuclear size on relativistic electron and the measured values are of greatest interest since it will reveal significant changes of the nuclear structure and may also improve the knowledge of fine structure correction.

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Section: Methodology 21 Nuclear Potential and Wavefunctionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Analytical Modeling of Nuclear Size Effect on Relativistic Electron in Hydrogen Atom

Adamu¹,

Hassan²,

Ahmad³

et al. 2020

NIPES

View full text Add to dashboard Cite

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“…Understanding the atomic spectra of the hydrogen atom drove the discovery of quantum mechanics in the 1920's. The measurement of the Lamb shift in 1947 and its explanation by Bethe in terms of atom's interaction with the quantum vacuum fluctuations ushered in a revolution in quantum electrodynamics [5][6][7]. Exploring the symmetries of the hydrogen atom has been an essential part of this progress.…”

Section: Brief History Of Symmetry In Quantum Mechanics and Its Role mentioning

confidence: 99%

“…This radiative shift accounted for about 96% of the measured shift. The insight that one needed to include the interaction of the atom with the vacuum fluctuations and how one could actually do it ushered in the modern world of quantum electrodynamics [7]. Here, we compute in the non-relativistic dipole approximation and to first order in the radiation field, as did Bethe, the radiative shift, but we use group theoretical methods based on the SO(4,2) symmetry of the non-relativistic hydrogen atom as developed in this paper.…”

Section: So(42) Calculation Of the Radiative Shift For The Schrodingmentioning

confidence: 99%

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Dynamical Symmetries of the H Atom, One of the Most Important Tools of Modern Physics: SO(4) to SO(4,2), Background, Theory, and Use in Calculating Radiative Shifts

Maclay

2020

Symmetry

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Understanding the hydrogen atom has been at the heart of modern physics. Exploring the symmetry of the most fundamental two body system has led to advances in atomic physics, quantum mechanics, quantum electrodynamics, and elementary particle physics. In this pedagogic review, we present an integrated treatment of the symmetries of the Schrodinger hydrogen atom, including the classical atom, the SO(4) degeneracy group, the non-invariance group or spectrum generating group SO(4,1), and the expanded group SO(4,2). After giving a brief history of these discoveries, most of which took place from 1935–1975, we focus on the physics of the hydrogen atom, providing a background discussion of the symmetries, providing explicit expressions for all of the manifestly Hermitian generators in terms of position and momenta operators in a Cartesian space, explaining the action of the generators on the basis states, and giving a unified treatment of the bound and continuum states in terms of eigenfunctions that have the same quantum numbers as the ordinary bound states. We present some new results from SO(4,2) group theory that are useful in a practical application, the computation of the first order Lamb shift in the hydrogen atom. By using SO(4,2) methods, we are able to obtain a generating function for the radiative shift for all levels. Students, non-experts, and the new generation of scientists may find the clearer, integrated presentation of the symmetries of the hydrogen atom helpful and illuminating. Experts will find new perspectives, even some surprises.

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