Martel Laura, Capelli Elisa, Body Monique, Klipfel Marco, Beneš Ondrej, Maksoud Louis, Raison Phillipe E, Suard Emmanuelle, Visscher Lucas, Bessada Catherine, Legein Christophe, Charpentier Thibault, Kovács Attila
European Commission, Joint Research Centre (JRC) , Postfach 2340 , D-76125 Karlsruhe , Germany.
Radiation Science & Technology Department, Nuclear Energy and Radiation Applications (NERA) , Delft University of Technology , Mekelweg 15 , 2629 JB Delft , The Netherlands.
Inorg Chem. 2018 Dec 17;57(24):15350-15360. doi: 10.1021/acs.inorgchem.8b02683. Epub 2018 Nov 26.
Because of its sensitivity to the atomic scale environment, solid-state NMR offers new perspectives in terms of structural characterization, especially when applied jointly with first-principles calculations. Particularly, challenging is the study of actinide-based materials because of the electronic complexity of the actinide cations and to the hazards due to their radioactivity. Consequently, very few studies have been published in this subfield. In the present paper, we report a joint experimental-theoretical analysis of thorium tetrafluoride, ThF, containing a closed-shell actinide (5f) cation. Its crystalline structure has been revisited in the present work using powder neutron diffraction experiments. The F NMR parameters of the seven F crystallographic sites have been modeled using an empirical superposition model, periodic first-principles calculations, and a cluster-based all-electron approach. On the basis of the atomic position optimized structure, a complete and unambiguous assignment of the F NMR resonances to the F sites has been obtained.
由于对原子尺度环境敏感,固态核磁共振在结构表征方面提供了新的视角,特别是与第一性原理计算联合应用时。尤其具有挑战性的是对锕系元素基材料的研究,这是由于锕系阳离子的电子复杂性以及它们放射性带来的危害。因此,该子领域发表的研究非常少。在本文中,我们报告了对含有闭壳层锕系元素(5f)阳离子的四氟化钍(ThF₄)的实验 - 理论联合分析。在本工作中,使用粉末中子衍射实验重新研究了其晶体结构。七个氟晶体学位置的¹⁹F核磁共振参数已使用经验叠加模型、周期性第一性原理计算和基于簇的全电子方法进行建模。基于原子位置优化结构,已获得¹⁹F核磁共振共振到氟位置的完整且明确的归属。
