Unidade de Ciências Químicas e Radiofarmacêuticas, Instituto Tecnológico e Nuclear, 2686-953 Sacavém, Portugal.
Phys Chem Chem Phys. 2011 Jul 28;13(28):12940-58. doi: 10.1039/c1cp20996e. Epub 2011 Jun 20.
The gas-phase thermochemistry of actinide monosulfides, AnS, was investigated experimentally and theoretically. Fourier transform ion cyclotron resonance mass spectrometry was employed to study the reactivity of An(+) and AnO(+) (An = Th, Pa, U, Np, Pu, Am and Cm) with CS(2) and COS, as well as the reactivity of the produced AnS(+) with oxidants (COS, CO(2), CH(2)O and NO). From these experiments, An(+)-S bond dissociation energies could be bracketed. Density functional theory studies of the energetics of neutral and monocationic AnS (An = Ac, Th, Pa, U, Np, Pu, Am and Cm) provided values for bond dissociation energies and ionization energies; the computed energetics of neutral and monocationic AnO were also obtained for comparison. The theoretical data, together with comparisons with known An(+)-O bond dissociation energies and M(+)-S and M(+)-O dissociation energies for the early transition metals, allowed for the refining of the An(+)-S bond dissociation energy ranges obtained from experiment. Examination of the reactivity of AnS(+) with dienes, coupled to comparisons with reactivities of the AnO(+) analogues, systematic considerations and the theoretical results, allowed for the estimation of the ionization energies of the AnS; the bond dissociation energies of neutral AnS were consequently derived. Estimates for the case of AcS were also made, based on correlations of the data for the other An and the electronic energetics of neutral and ionic An. The nature of the bonding in the elementary molecular actinide chalcogenides (oxides and sulfides) is discussed, based on both the experimental data and the computed electronic structures. DFT calculations of ionization energies for the actinide atoms and the diatomic sulfides and oxides are relatively reliable, but the calculation of bond dissociation energies is not uniformly satisfactory, either with DFT or CCSD(T). A key conclusion from both the experimental and theoretical results is that the 5f electrons do not substantially participate in actinide-sulfur bonding. We emphasize that actinides form strikingly strong bonds with both oxygen and sulfur.
镧系元素单硫化物的气相热化学已通过实验和理论进行了研究。傅里叶变换离子回旋共振质谱法被用于研究 An(+) 和 AnO(+)(An = Th、Pa、U、Np、Pu、Am 和 Cm)与 CS(2) 和 COS 的反应性,以及生成的 AnS(+)与氧化剂(COS、CO(2)、CH(2)O 和 NO)的反应性。通过这些实验,可以确定 An(+)-S 键的键离解能。中性和一价镧系元素 AnS(An = Ac、Th、Pa、U、Np、Pu、Am 和 Cm)的密度泛函理论研究提供了键离解能和电离能的值;还获得了计算得到的中性和一价镧系元素 AnO 的能值,以供比较。理论数据,以及与已知的 An(+)-O 键离解能和早期过渡金属的 M(+)-S 和 M(+)-O 离解能的比较,使从实验中获得的 An(+)-S 键离解能范围得以精化。通过与 AnO(+)类似物的反应性比较,对 AnS(+)与二烯的反应性进行了考察,并进行了系统的考虑和理论结果分析,从而可以估算 AnS 的电离能;因此,推导出中性 AnS 的键离解能。基于对其他 An 的数据的相关性以及中性和离子 An 的电子能,也对 AcS 进行了估计。基于实验数据和计算得到的电子结构,讨论了元素镧系元素的卤化物(氧化物和硫化物)中键的本质。对于锕系元素原子和双原子硫化物和氧化物的电离能的 DFT 计算相对可靠,但无论是 DFT 还是 CCSD(T),键离解能的计算都不完全令人满意。从实验和理论结果中得出的一个关键结论是,5f 电子并没有实质性地参与锕系元素-硫键的形成。我们强调,锕系元素与氧和硫形成了惊人的强键。
