Demidov Yuriy A, Shalaevsky Alexander A, Oleynichenko Alexander V, Rusakov Alexander A
B. P. Konstantinov Petersburg Nuclear Physics Institute of National Research Center "Kurchatov Institute" (NRC "Kurchatov Institute" - PNPI), Orlova Roscha, 1, 188300 Gatchina, Russia.
St. Petersburg Electrotechnical University "LETI", 197376 St. Petersburg, Russia.
Phys Chem Chem Phys. 2024 Sep 18;26(36):23823-23834. doi: 10.1039/d4cp01868k.
The fascination with superheavy elements (SHE) spans the nuclear physics, astrophysics, and theoretical chemistry communities. Extreme relativistic effects govern these elements' chemistry and challenge the traditional notion of the periodic law. The experimental quest for SHE critically depends on theoretical predictions of these elements' properties, especially chemical homology, which allows for successful prototypical experiments with more readily available lighter homologues of SHE. This work is a comprehensive quantum-chemical investigation into astatine (At) as a non-intuitive homologue of element 113, nihonium (Nh). Combining relativistic coupled-cluster and density functional theory approaches, we model the behaviour of At and AtOH in thermochromatographic experiments on a pristine gold surface. Insights into the electronic structure of AtOH and NhOH and accurate estimates of At-gold and AtOH-gold adsorption energies rationalise recent experimental findings and justify the use of At as a chemical homologue of Nh for the successful design of future experiments on Nh detection and chemical characterisation.
对超重元素(SHE)的研究兴趣跨越了核物理、天体物理和理论化学领域。极端相对论效应支配着这些元素的化学性质,并挑战了传统的周期律概念。对超重元素的实验探索严重依赖于对这些元素性质的理论预测,特别是化学同源性,这使得利用更容易获得的超重元素较轻的同系物进行成功的原型实验成为可能。这项工作是对砹(At)作为113号元素 nihonium(Nh)的非直观同系物进行的全面量子化学研究。结合相对论耦合簇和密度泛函理论方法,我们模拟了砹(At)和AtOH在原始金表面热色谱实验中的行为。对AtOH和NhOH电子结构的深入了解以及对At-金和AtOH-金吸附能的准确估计,使最近的实验结果合理化,并证明了将At用作Nh的化学同系物以成功设计未来Nh检测和化学表征实验的合理性。
