Second-order Rayleigh–Schrödinger perturbation theory for the GRASP2018 package: Core–valence correlations

IF 0.3 4区物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY

Lithuanian Journal of Physics Pub Date : 2024-02-23 DOI:10.3952/physics.2024.64.1.3

G. Gaigalas, P. Rynkun, L. Kitovienė

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引用次数: 0

Abstract

The General Relativistic Atomic Structure package [GRASP2018, C. Froese Fischer, G. Gaigalas, P. Jönsson, and J. Bieroń, Comput. Phys. Commun. (2019), DOI: 10.1016/j.cpc.2018.10.032] is based on multiconfiguration Dirac– Hartree–Fock and relativistic configuration interaction (RCI) methods for energy structure calculations. The atomic state function used in the program is built from the set of configuration state functions (CSFs). The valence–valence, core–valence and core–core correlations are explicitly included through expansions over CSFs in RCI. We present a combination of RCI and the stationary second-order Rayleigh–Schrödinger many-body perturbation theory in an irreducible tensorial form to account for electron core–valence correlations when an atom or ion has any number of valence electrons. This newly developed method, which offers two ways of use, allows a significant reduction of the CSF space for complex atoms and ions. We also demonstrate how the method and program works for the energy structure calculation of Cl III ion.

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用于 GRASP2018 软件包的二阶瑞利-薛定谔微扰理论：核价相关性

广义相对论原子结构软件包[GRASP2018, C. Froese Fischer, G. Gaigalas, P. Jönsson, and J. Bieroń, Comput.Phys.(2019), DOI: 10.1016/j.cpc.2018.10.032] 基于多构型 Dirac- Hartree-Fock 和相对论构型相互作用（RCI）方法进行能量结构计算。程序中使用的原子态函数是由一组构型态函数（CSF）构建的。在 RCI 中，价-价、核-价和核-核相关性通过对 CSF 的展开被明确包含在内。我们将 RCI 与静态二阶瑞利-薛定谔多体扰动理论相结合，以不可还原的张量形式来解释原子或离子具有任意数量价电子时的电子核价相关性。这种新开发的方法有两种使用方式，可以显著缩小复杂原子和离子的 CSF 空间。我们还演示了该方法和程序如何用于 Cl III 离子的能量结构计算。

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来源期刊

Lithuanian Journal of Physics 物理-物理：综合

CiteScore

0.90

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： The main aim of the Lithuanian Journal of Physics is to reflect the most recent advances in various fields of theoretical, experimental, and applied physics, including: mathematical and computational physics; subatomic physics; atoms and molecules; chemical physics; electrodynamics and wave processes; nonlinear and coherent optics; spectroscopy.