通过原子层沉积制备的分子发色团-催化剂组装体进行的合成、表征及水氧化。“木乃伊”策略。
Synthesis, characterization, and water oxidation by a molecular chromophore-catalyst assembly prepared by atomic layer deposition. The "mummy" strategy.
作者信息
Lapides A M, Sherman B D, Brennaman M K, Dares C J, Skinner K R, Templeton J L, Meyer T J
机构信息
Department of Chemistry , University of North Carolina at Chapel Hill , CB 3290 , Chapel Hill , NC 27599 , USA . Email:
出版信息
Chem Sci. 2015 Nov 1;6(11):6398-6406. doi: 10.1039/c5sc01752a. Epub 2015 Jul 31.
Abstract
A new strategy for preparing spatially-controlled, multi-component films consisting of molecular light absorbing chromophores and water oxidation catalysts on high surface area, mesoporous metal oxide surfaces is described. Atomic layer deposition (ALD) is used to embed a surface-bound chromophore in a thin layer of inert AlO, followed by catalyst binding to the new oxide surface. In a final step, catalyst surface-binding is stabilized by a subsequent ALD overlayer of AlO. The ALD assembly procedure bypasses synthetic difficulties arising from the preparation of phosphonic acid derivatized, covalently-linked assemblies. An ALD mummy-based assembly has been used to demonstrate photoelectrochemical dehydrogenation of hydroquinone. Electrocatalytic water oxidation at pH 8.8 is observed over a 2 hour electrolysis period and light-assisted water oxidation over a 6 hour photolysis period with O detected with a generator-collector electrode configuration.
摘要
描述了一种在高比表面积介孔金属氧化物表面制备由分子光吸收发色团和水氧化催化剂组成的空间可控多组分薄膜的新策略。原子层沉积(ALD)用于将表面结合的发色团嵌入惰性AlO的薄层中,随后催化剂与新的氧化物表面结合。在最后一步中,通过随后的AlO ALD覆盖层稳定催化剂表面结合。ALD组装过程绕过了由膦酸衍生化的共价连接组装体的制备所产生的合成困难。基于ALD木乃伊的组装已用于证明对苯二酚的光电化学脱氢。在2小时的电解期间观察到在pH 8.8下的电催化水氧化,在6小时的光解期间观察到光辅助水氧化,使用发生器-收集器电极配置检测到O。
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