Moskaleva Lyudmila V, Krüger Sven, Spörl Andreas, Rösch Notker
Institut für Physikalische und Theoretische Chemie, Technische Universität München, 85747 Garching, Germany.
Inorg Chem. 2004 Jun 28;43(13):4080-90. doi: 10.1021/ic035450h.
We have studied the solvation of uranyl, UO(2)(2+), and the reduced species UO(OH)(2+) and U(OH)(2)(2+) systematically using three levels of approximation: direct application of a continuum model (M1); explicit quantum-chemical treatment of the first hydration sphere (M2); a combined quantum-chemical/continuum model approach (M3). We have optimized complexes with varying numbers of aquo ligands (n = 4-6) and compared their free energies of solvation. Models M1 and M2 have been found to recover the solvation energy only partially, underestimating it by approximately 100 kcal/mol or more. With our best model M3, the calculated hydration free energy Delta(h)G degrees of UO(2)(2+) is about -420 kcal/mol, which shifts to about -370 kcal/mol when corrected for the expected error of the model. This value agrees well with the experimentally determined interval, -437 kcal/mol < Delta(h)G degrees < -318 kcal/mol. Complexes with 5 and 6 aquo ligands have been found to be about equally favored with models M2 and M3. The same solvation models have been applied to a two-step reduction of UO(2)(2+) by water, previously theoretically studied in the gas phase. Our results show that the solvation contribution to the reaction free energy, about 60 kcal/mol, dominates the endoergicity of the reduction.
我们使用三种近似水平系统地研究了铀酰离子UO₂²⁺以及还原态物种UO(OH)²⁺和U(OH)₂²⁺的溶剂化作用:直接应用连续介质模型(M1);对第一水合层进行显式量子化学处理(M2);量子化学/连续介质模型相结合的方法(M3)。我们优化了具有不同数量水合配体(n = 4 - 6)的配合物,并比较了它们的溶剂化自由能。已发现模型M1和M2只能部分恢复溶剂化能,低估了约100千卡/摩尔或更多。使用我们最好的模型M3,计算得到的UO₂²⁺的水合自由能ΔₕG°约为 - 420千卡/摩尔,经模型预期误差校正后变为约 - 370千卡/摩尔。该值与实验测定的区间 - 437千卡/摩尔 < ΔₕG° < - 318千卡/摩尔吻合良好。已发现具有5个和6个水合配体的配合物在模型M2和M3中受到的青睐程度大致相同。相同的溶剂化模型已应用于UO₂²⁺被水两步还原的过程,此前已在气相中进行过理论研究。我们的结果表明,溶剂化对反应自由能的贡献约为60千卡/摩尔,主导了还原反应的吸能性。