Undulating Potentials of Rydberg Σ+-States of Me–Rg Molecules: NonEmpirical Modeling of the Na–He Exciplex

IF 0.7 Q4 CHEMISTRY, MULTIDISCIPLINARY

Moscow University Chemistry Bulletin Pub Date : 2024-10-16 DOI:10.3103/S0027131424700305

S. V. Kozlov, E. A. Pazyuk, A. V. Stolyarov

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Abstract

The multireference configuration interaction method based on single and double excitations (MR–CISD), l-independent core polarization potential (CPP), and diffuse function-saturated cc-pVQZ and aug-cc-pV5Z basis sets for Na and He atoms, respectively, is used to perform nonrelativistic calculations of potential energy curves and permanent dipole moment functions for the ground and excited electronic states of the exciplex Na–He molecule up to the Na(6²S) state. The ab initio results obtained within a wide range of internuclear distances R [1.7, 20.0] (Å) quantitatively confirm the undulating behavior of interatomic potentials, predicted in the framework of the inelastic scattering theory. It is established that at large R the interatomic potentials and dipole moments of highly excited (3, 6, 10)²Σ⁺ states, converging to the Na (n = 4, 5, 6²S) + He(2²S) atomic limits, are modulated by the nodal structure of the radial Rydberg wave function (n > 3) of the s-electron of an Na atom during its scattering on a remote He atom.

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Me-Rg 分子的 Rydberg Σ+ 态的波动电位：Na-He 复合物的非经验建模

基于单激发和双激发（MR-CISD）的多参量构型相互作用方法、与l无关的核极化势（CPP）以及扩散函数饱和的cc-pVQZ和aug-cc-pV5Z基集分别用于Na原子和He原子，对Na-He分子直到Na(62S)态的基态和激发电子态的势能曲线和永久偶极矩函数进行了非相对论计算。在广泛的核间距 R [1.7, 20.0] (Å) 范围内获得的非正则计算结果定量地证实了非弹性散射理论框架中预测的原子间势能的起伏行为。研究证实，在大 R 范围内，高度激发 (3, 6, 10)2Σ+ 态的原子间势能和偶极矩趋近于 Na (n = 4, 5, 62S) + He(22S) 原子极限，在 Na 原子对远处 He 原子的散射过程中，受到 Na 原子 s 电子的径向雷德贝格波函数 (n > 3) 的节点结构的调制。

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来源期刊

Moscow University Chemistry Bulletin CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

1.30

自引率

14.30%

发文量

期刊介绍： Moscow University Chemistry Bulletin is a journal that publishes review articles, original research articles, and short communications on various areas of basic and applied research in chemistry, including medical chemistry and pharmacology.