团簇化学中的自旋轨道效应:合理化其性质的考虑和应用

IF 6.1 Q2 CHEMISTRY, PHYSICAL
À. Muñoz-Castro, R. Arratia‐Pérez
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引用次数: 0

摘要

在含重元素的物种中通常考虑到相对论效应,给科学界带来了令人振奋的研究案例。标量和自旋轨道效应需要正确地评估这类物质的几何和电子结构,其中通常包括标量修正。为了考虑空间坐标和自旋坐标之间相互作用产生的自旋轨道项,需要对称的双值点群,从而导致总角动量(j)函数和原子或分子旋量,而不是纯轨道-角动量(l)和原子或分子轨道。在这里,我们回顾了自旋轨道耦合在裸和配体保护的金属团簇中的作用,从早期到现在的工作,导致一个更全面的相对论量子化学框架。结果,电子结构被改变,导致计算的分子性质发生变化,这通常提高了理论和实验之间的一致性,从而使从经典无机化学的角度意想不到的实验结果进一步合理化。本文总结了自旋轨道耦合在重元素团团化学中的部分现代应用,鼓励在与元素周期表平等的基础上进一步处理,以便将该术语纳入实验和理论化学家以及材料科学家的通用词汇中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Spin–orbit effects in cluster chemistry: Considerations and applications for rationalization of their properties
Relativistic effects are usually taken into account in heavy-element-containing species, bringing to the scientific community stimulating cases of study. Scalar and spin–orbit effects are required to properly evaluate both the geometrical and electronic structures of such species, where, generally, scalar corrections are included. In order to take into account the spin–orbit term resulting from the interaction between the spatial and spin coordinates, double-valued point groups of symmetry are required, leading to total angular momenta (j) functions and atomic or molecular spinors, instead of pure orbital-angular momenta (l) and atomic or molecular orbitals. Here, we reviewed the role of spin–orbit coupling in bare and ligand-protected metallic clusters, from early to current works, leading to a more comprehensive relativistic quantum chemistry framework. As a result, the electronic structure is modified, leading to a variation in the calculated molecular properties, which usually improves the agreement between theory and experiment, allowing furthering rationalize of experimental results unexpected from a classical inorganic chemistry point of view. This review summarizes part of the modern application of spin–orbit coupling in heavy-elements cluster chemistry, where further treatment on an equal footing basis along with the periodic table is encouraged in order to incorporate such term in the general use vocabulary of both experimental and theoretical chemist and material scientist.
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