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Main Author: Frolov, Alexei M.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.01083
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author Frolov, Alexei M.
author_facet Frolov, Alexei M.
contents Methods of angular momenta are modified and used to solve some actual problems in quantum mechanics. In particular, we re-derive some known formulas for analytical and numerical calculations of matrix elements of the vector physical quantities. These formulas are applied to a large number of quantum systems which have an explicit spherical symmetry. Multiple commutators of different powers of the angular momenta $\hat{\bf J}^{2}$ and vector-operator $\hat{\bf A}$ are determined in the general form. Calculations of the expectation values averaged over orbital angular momenta are also described in detail. This effective and elegant old technique, which was successfully used by E. Fermi and A. Bohr, is almost forgotten in modern times. We also discuss quantum systems with additional relations (or constraints) between some vector-operators and orbital angular momentum. For similar systems such relations allow one to obtain some valuable additional information about their properties, including the bound state spectra, correct asymptotics of actual wave functions, etc. As an example of unsolved problems we consider applications of the algebras of angular momenta to investigation of the one-electron, two-center (Coulomb) problem $(Q_1, Q_2)$. For this problem it is possible to obtain the closed analytical solutions which are written as the `correct' linear combinations of products of the two one-electron wave functions of the hydrogen-like ions with the nuclear charges $Q_1 + Q_2$ and $Q_1 - Q_2$, respectively. However, in contrast with the usual hydrogen-like ions such hydrogenic wave functions must be constructed in three-dimensional pseudo-Euclidean space with the metric (-1,-1,1).
format Preprint
id arxiv_https___arxiv_org_abs_2411_01083
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On matrix elements of the vector physical quantities
Frolov, Alexei M.
Atomic Physics
Methods of angular momenta are modified and used to solve some actual problems in quantum mechanics. In particular, we re-derive some known formulas for analytical and numerical calculations of matrix elements of the vector physical quantities. These formulas are applied to a large number of quantum systems which have an explicit spherical symmetry. Multiple commutators of different powers of the angular momenta $\hat{\bf J}^{2}$ and vector-operator $\hat{\bf A}$ are determined in the general form. Calculations of the expectation values averaged over orbital angular momenta are also described in detail. This effective and elegant old technique, which was successfully used by E. Fermi and A. Bohr, is almost forgotten in modern times. We also discuss quantum systems with additional relations (or constraints) between some vector-operators and orbital angular momentum. For similar systems such relations allow one to obtain some valuable additional information about their properties, including the bound state spectra, correct asymptotics of actual wave functions, etc. As an example of unsolved problems we consider applications of the algebras of angular momenta to investigation of the one-electron, two-center (Coulomb) problem $(Q_1, Q_2)$. For this problem it is possible to obtain the closed analytical solutions which are written as the `correct' linear combinations of products of the two one-electron wave functions of the hydrogen-like ions with the nuclear charges $Q_1 + Q_2$ and $Q_1 - Q_2$, respectively. However, in contrast with the usual hydrogen-like ions such hydrogenic wave functions must be constructed in three-dimensional pseudo-Euclidean space with the metric (-1,-1,1).
title On matrix elements of the vector physical quantities
topic Atomic Physics
url https://arxiv.org/abs/2411.01083