Department of Chemistry, University of California , Irvine, California 92697, United States.
J Am Chem Soc. 2016 Nov 2;138(43):14174-14177. doi: 10.1021/jacs.6b05851. Epub 2016 Jul 22.
Electrocatalytic activity of a water-soluble nickel complex, [Ni(DHMPE)] (DHMPE = 2-bis(di(hydroxymethyl)phosphino)ethane), for the hydrogen evolution reaction (HER) at pH 1 is reported. The catalyst functions at a rate of ∼10 s (k) with high Faradaic efficiency. Quantification of the complex before and after 18+ hours of electrolysis reveals negligible decomposition under catalytic conditions. Although highly acidic conditions are common in electrolytic cells, this is a rare example of a homogeneous catalyst for HER that functions with high stability at low pH. The stability of the compound and proposed catalytic intermediates enabled detailed mechanistic studies. The thermodynamic parameters governing electron and proton transfer were used to determine the appropriate reductants and acids to access the catalytic cycle in a stepwise fashion, permitting direct spectroscopic identification of intermediates. These studies support a mechanism for proton reduction that proceeds through two-electron reduction of the nickel(II) complex, protonation to generate [HNi(DHMPE)], and further protonation to initiate hydrogen bond formation.
报道了一种水溶性镍配合物[Ni(DHMPE)](DHMPE=2-双(二羟甲基)膦基)乙烷)在 pH 1 下对析氢反应(HER)的电催化活性。该催化剂的反应速率约为 10 s-1(k),法拉第效率高。对 18 小时以上电解前后的配合物进行定量分析表明,在催化条件下几乎没有分解。虽然在电解槽中常见的是高度酸性条件,但这是在低 pH 值下具有高稳定性的 HER 均相催化剂的罕见实例。化合物和提出的催化中间体的稳定性使详细的机理研究成为可能。控制电子和质子转移的热力学参数用于确定合适的还原剂和酸,以逐步进入催化循环,从而可以直接通过光谱鉴定中间体。这些研究支持了一种通过镍(II)配合物的两电子还原、质子化生成[HNi(DHMPE)]以及进一步质子化引发氢键形成来进行质子还原的机制。
