Square-Planar Nickel Bis(phosphinopyridyl) Complexes for Long-Lived Photocatalytic Hydrogen Evolution.

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY JACS Au Pub Date : 2024-09-26 eCollection Date: 2024-10-28 DOI:10.1021/jacsau.4c00714
Chien-Ting Wu, Hung-Ruei Pan, Chi-Tien Hsieh, Yu-Syuan Tsai, Pei-Juan Liao, Shuo-Huan Chiang, Che-Min Chu, Wei-Kai Shao, Yi-Rong Lien, Yu-Wei Chen, Tsung-Lun Kan, Vincent C-C Wang, Mu-Jeng Cheng, Hua-Fen Hsu
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Abstract

Phosphinopyridyl ligands are used to synthesize a class of Ni(II) bis(chelate) complexes, which have been comprehensively characterized in both solid and solution phases. The structures display a square-planar configuration within the primary coordination sphere, with axially positioned labile binding sites. Their electrochemical data reveal two redox couples during the reduction process, suggesting the possibility of accessing two-electron reduction states. Significantly, these complexes serve as robust catalysts for homogeneous photocatalytic H2 evolution. In a system utilizing an organic photosensitizer and a sacrificial electron donor, an optimal turnover number of 27,100 is achieved in an alcohol-containing aqueous solution. A series of photophysical and electrochemical measurements were conducted to elucidate the reaction mechanism of photocatalytic hydrogen generation. Density function theory calculations propose a catalytic pathway involving two successive one-electron reduction steps, followed by two proton discharges. The sustained photocatalytic activity of these complexes stems from their distinct ligand system, which includes phosphine and pyridine donors that aid in stabilizing the low oxidation states of the Ni center.

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用于长寿命光催化氢气转化的方形平面双(膦酰基吡啶)镍配合物。
磷吡啶配体被用来合成一类镍(II)双(螯合物)配合物,这些配合物在固相和溶液相中都得到了全面的表征。这些配合物的结构在主配位层内呈方形构型,并具有轴向定位的易结合位点。它们的电化学数据显示,在还原过程中存在两个氧化还原偶,这表明存在进入双电子还原态的可能性。值得注意的是,这些复合物是均相光催化 H2 演化的强力催化剂。在一个利用有机光敏剂和牺牲电子供体的系统中,在含酒精的水溶液中实现了 27,100 的最佳周转次数。为了阐明光催化制氢的反应机理,研究人员进行了一系列光物理和电化学测量。密度函数理论计算提出了一种催化途径,包括两个连续的单电子还原步骤,然后是两次质子放电。这些复合物的持续光催化活性源于它们独特的配体系统,其中包括有助于稳定镍中心低氧化态的膦和吡啶供体。
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