Direct Evidence for Buffer-Enhanced Proton-Coupled Electron Transfer in Metal Aquo Bond Formation

Matthew, Kessinger, Gerald, Meyer, Thomas, Whittemore, Silvia, Grandi, Evgeny, Danilov, Stefano, Caramori, Felix, Castellano
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Abstract

Proton-coupled electron transfer (PCET) reactions play a crucial role in the interconversion of metal-aqua and metal-hydroxo species present in transition metal complexes and oxide surfaces (M(III)-OH + e− + H+ M(II)-OH2). For ruthenium-based water oxidation catalysts, PCET reactions involved in the mechanism of oxygen evolution have demonstrated a strong dependence on the identity and concentration of the proton donor and acceptor with significant rate enhancements observed for electrocatalysis performed in acetate, phosphate, and borate buffered electrolytes. However, the systematic study of this phenomenon has been hampered by the inability to independently measure discrete rates for electron transfer (ET) and proton transfer (PT) under electrochemical applied potentials. Herein, the PCET kinetics and mechanism of metal aqua bond formation in a ruthenium water oxidation catalyst [Ru(tpy)(bpy′)H2O]2+, Ru(II)−OH2 where tpy is 2,2′:6′,2″-terpyridine and bpy′ is 4,4′-diaminopropylsilatrane-2,2′-bypyridine were investigated at a conductive metal oxide interface as a function of buffer identity and concentration. The reaction of interest was triggered by visible light excitation of the catalyst and the kinetics of the independent ET and PT steps of the PCET mechanism were determined through nanosecond transient absorption spectroscopy. Kinetic measurements performed in aqueous acetate, phosphate, or borate buffer solutions revealed two distinct regimes of PT kinetics solely dependent on the buffer concentration. At the greatest buffer concentrations investigated (2 M acetate) spectral signals corresponding to the discreet ET and PT steps were absent indicative in a change in underlying PCET mechanism. Likewise, kinetic modeling indicated that PT from protonated acetate or phosphate occurred with rate constants that were 2-4 orders of magnitude greater than those for bulk water. In all, these results suggest that the presence of buffer-bases can significantly enhance PCET rates and, in this reaction, may alter the underlying mechanism.
缓冲增强质子耦合电子转移在金属水杉键形成中的直接证据
质子耦合电子转移(PCET)反应在过渡金属络合物和氧化物表面存在的金属-水和金属-羟基物种(M(III)-OH + e- + H+ M(II)-OH2)的相互转化中起着至关重要的作用。对于钌基水氧化催化剂,氧进化机理中涉及的 PCET 反应与质子供体和受体的特性和浓度密切相关,在醋酸盐、磷酸盐和硼酸盐缓冲电解质中进行电催化时,可观察到显著的速率增强。然而,由于无法独立测量电化学外加电位下电子转移(ET)和质子转移(PT)的离散速率,对这一现象的系统研究一直受到阻碍。本文研究了钌水氧化催化剂[Ru(tyy)(bpy′)H2O]2+、Ru(II)-OH2(其中tyy为2,2′:其中 tpy 是 2,2′:6′,2″-三吡啶,bpy′ 是 4,4′-二氨基丙基硅烷-2,2′-吡啶。催化剂的可见光激发触发了感兴趣的反应,并通过纳秒瞬态吸收光谱测定了 PCET 机制中独立的 ET 和 PT 步骤的动力学。在醋酸盐、磷酸盐或硼酸盐缓冲水溶液中进行的动力学测量显示,PT 动力学的两个不同阶段完全取决于缓冲液的浓度。在所研究的最大缓冲液浓度(2 M 乙酸)下,与不同的 ET 和 PT 步骤相对应的光谱信号不存在,这表明 PCET 的基本机制发生了变化。同样,动力学建模表明,质子化的醋酸盐或磷酸盐发生 PT 的速率常数比体水的速率常数大 2-4 个数量级。总之,这些结果表明,缓冲碱的存在可显著提高 PCET 的速率,并可能改变该反应的基本机理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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