Two routes to hydrogen evolution for a Co-polypyridyl complex with two open sites

IF 2.9 Q3 CHEMISTRY, PHYSICAL
Liqin Xue Toro, S. Kiriakidi, A. Thapper, S. Ott, M. Lundberg
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引用次数: 1

Abstract

Cobalt polypyridyl complexes efficiently catalyze hydrogen evolution in aqueous media and exhibit high stability under reducing conditions. Their stability and activity can be tuned through electronic and steric considerations, but the rationalization of these effects requires detailed mechanistic understanding. As an example, tetradentate ligands with two non-permanently occupied coordination sites show higher activity with these sites in cis compared to trans configuration. Here reaction mechanisms of the Co-polypyridyl complex [CoII(bpma)Cl2] (bpma = bipyridinylmethyl-pyridinylmethyl-methyl-amine) have been studied using hybrid density-functional theory. This complex has two exchangeable cis sites, and provides a flexible ligand environment with both pyridyl and amine coordination. Two main pathways with low barriers are found. One pathway, which includes both open sites, is hydrogen evolution from a CoII-H intermediate with a water ligand as the proton donor. In the second pathway H–H bond formation occurs between the hydride and the protonated bpma ligand, with one open site acting as a spectator. The two pathways have similar barriers at higher pH, while the latter becomes more dominant at lower pH. The calculations consider a large number of interconnected variables; protonation sites, isomers, spin multiplicities, and the identities of the open binding sites, as well as their combinations, thus exploring many simultaneous dimensions within each pathway. The results highlight the effects of having two open cis-coordination sites and how their relative binding affinities change during the reaction pathway. They also illustrate why CoII-H intermediates are more active than CoIII-H ones, and why pyridyl protonation gives lower reaction barriers than amine protonation.
具有两个开放位点的共聚吡啶配合物的两种析氢途径
钴多吡啶配合物在水性介质中有效催化析氢,并在还原条件下表现出高稳定性。它们的稳定性和活性可以通过电子和空间因素来调节,但这些效应的合理化需要详细的机制理解。例如,与反式构型相比,具有两个非永久占据的配位位点的四齿配体在顺式构型中显示出更高的活性。本文用杂化密度泛函理论研究了钴-多吡啶配合物[CoII(bpma)Cl2](bpma=联吡啶基甲基吡啶基甲基甲胺)的反应机理。该配合物具有两个可交换的顺式位点,并提供了具有吡啶基和胺配位的柔性配体环境。发现了两种低屏障的主要途径。一种包括两个开放位点的途径是从以水配体为质子供体的CoII-H中间体析氢。在第二种途径中,氢化物和质子化的bpma配体之间形成H–H键,其中一个开放位点充当旁观者。这两种途径在较高的pH下具有相似的屏障,而后者在较低的pH下变得更具优势。计算考虑了大量相互关联的变量;质子化位点、异构体、自旋多重性、开放结合位点的身份以及它们的组合,从而探索每个途径中的许多同时维度。结果强调了具有两个开放的顺式配位位点的影响,以及它们的相对结合亲和力在反应过程中如何变化。他们还说明了为什么CoII-H中间体比CoIII-H中间体更具活性,以及为什么吡啶基质子化比胺质子化给出更低的反应势垒。
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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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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