在酸性水中用电催化方法实现分子钴四氮大环的氢析出反应。

Electrocatalytic hydrogen evolution in acidic water with molecular cobalt tetraazamacrocycles.

机构信息

Department of Chemistry and Chemical Engineering, California Institute of Technology, 1200 East California Boulevard, Pasadena, California 91125, USA.

出版信息

J Am Chem Soc. 2012 Feb 15;134(6):3164-70. doi: 10.1021/ja210661k. Epub 2012 Feb 6.

DOI:10.1021/ja210661k

PMID:22280515

Abstract

A series of water-soluble molecular cobalt complexes of tetraazamacrocyclic ligands are reported for the electrocatalytic production of H(2) from pH 2.2 aqueous solutions. The comparative data reported for this family of complexes shed light on their relative efficiencies for hydrogen evolution in water. Rotating disk electrode voltammetry data are presented for each of the complexes discussed, as are data concerning their respective pH-dependent electrocatalytic activity. In particular, two diimine-dioxime complexes were identified as exhibiting catalytic onset at comparatively low overpotentials relative to other reported homogeneous cobalt and nickel electrocatalysts in aqueous solution. These complexes are stable at pH 2.2 and produce hydrogen with high Faradaic efficiency in bulk electrolysis experiments over time intervals ranging from 2 to 24 h.

摘要

本文报道了一系列水溶性四氮大环配体的钴分子配合物，可用于在 pH 2.2 的水溶液中电催化生产氢气。该系列配合物的对比数据阐明了它们在水中析氢反应的相对效率。本文给出了所讨论的每个配合物的旋转圆盘电极伏安数据，以及与各自 pH 依赖性电催化活性有关的数据。特别地，两种二亚胺-二肟配合物被鉴定为在相对于其他报道的在水溶液中的均相钴和镍电催化剂具有相对低的过电势下表现出催化起始。这些配合物在 pH 2.2 下稳定，并且在 2 至 24 小时的时间间隔内的批量电解实验中以高法拉第效率产生氢气。

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在酸性水中用电催化方法实现分子钴四氮大环的氢析出反应。

Electrocatalytic hydrogen evolution in acidic water with molecular cobalt tetraazamacrocycles.

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