Biomedical Equipment Technology Program, Istanbul Aydin University, Istanbul 34295, Turkey.
Inorg Chem. 2012 Oct 15;51(20):10850-5. doi: 10.1021/ic3013359. Epub 2012 Oct 1.
Recently it was discovered that the iron coordination complex L(N4)Fe(II)(OTf)(2) (1) (L(N4) = neutral tetraazadendate ligand and OTf = OSO(2)CF(3)) and its analogues are efficient water oxidizing catalysts (WOCs) in aqueous acidic solution with excess amount of ceric(IV) ammonium nitrate (CAN), Ce(IV)(NO(3))(6)(2), as sacrificial oxidants. The probable mechanism of water oxidation by these catalysts was explored on the basis of density functional theory (DFT) and time-dependent DFT (TD-DFT) calculations for 1 as a representative WOC. We examined the conversion of 1 to the resting intermediate L(N4)Fe(IV)(O)(OH(2)) [2(IV)] as well as two catalytic cycles involving 2(IV): one proposed by Fillol et al. [Nat. Chem. 2011, 3, 1] in which the Fe oxidation states of the intermediate species vary from +2 to +5, and the alternative cycle in which they remain constant at +4. In addition, we investigated the role of the sacrificial oxidant CAN in driving the catalytic cycle. Our DFT and TD-DFT calculations confirm the experimental observation that 2(IV) is the resting species, and indicate that the catalytic cycle in which the Fe oxidation states of the intermediate species remain at +4 is energetically more favorable.
最近发现,铁配位配合物 L(N4)Fe(II)(OTf)(2)(1)(L(N4)=中性四氮杂环十四烷配体,OTf=OSO(2)CF(3))及其类似物在含有过量的硝酸铈(IV)铵(CAN),Ce(IV)(NO(3))(6)(2)的酸性水溶液中是高效的水氧化催化剂(WOCs),CAN 作为牺牲氧化剂。根据密度泛函理论(DFT)和时间相关的 DFT(TD-DFT)计算,我们探索了这些催化剂的水氧化的可能机制,以 1 作为代表性的 WOC。我们研究了 1 向休息中间体L(N4)Fe(IV)(O)(OH(2)) [2(IV)]的转化,以及两个涉及 2(IV)的催化循环:一个是 Fillol 等人提出的[Nat. Chem. 2011, 3, 1],其中中间物种的 Fe 氧化态从+2 变为+5,另一个循环中它们保持在+4 不变。此外,我们还研究了牺牲氧化剂 CAN 在驱动催化循环中的作用。我们的 DFT 和 TD-DFT 计算证实了实验观察到的 2(IV)是休息物种的结果,并表明中间物种的 Fe 氧化态保持在+4 的催化循环在能量上更有利。
