具有生物启发烯丙基嗪配体的三钌二亚胺配合物的光谱研究

IF 3 4区 化学 Q3 CHEMISTRY, PHYSICAL
Nina Hagmeyer, Alexander Schwab, Nabil Mroweh, Caitlin McManus, Maneesha Varghese, Jean-Marie Mouesca, Serge Gambarelli, Stephan Kupfer, Murielle Chavarot-Kerlidou, Benjamin Dietzek-Ivanšić
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引用次数: 0

摘要

在多电子氧化还原过程(如太阳能燃料生产)中,同时充当光敏剂和电子存储单元的分子电荷积累系统很有意义。为此,我们对 RuL1 的光物理特性进行了研究,RuL1 是一种三二亚胺钌配合物,其生物启发结构主题是一种烯丙基嗪配体。研究内容包括吸收、发射、共振拉曼和瞬态吸收光谱,并结合量子化学模拟来确定该复合物的光驱动反应性。此外,还采用了光谱电化学方法来深入分析还原复合物的光学特性。最后,利用三乙醇胺作为电子源,结合氧化还原滴定法进行了光解实验,结果表明可见光照射会触发形成 RuL1 的双还原单质子化衍生物,其中两个氧化还原等价物都储存在基于烯丙基嗪的配体上。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Spectroscopic Investigation of a Ruthenium Tris‐diimine Complex Featuring a Bioinspired Alloxazine Ligand
Molecular charge accumulating systems that act as both, photosensitizer and electron storage unit, are of interest in the context of multielectron redox processes, e.g. in solar fuel production. To this end, the photophysical properties of RuL1, a ruthenium tris‐diimine complex with an alloxazine‐based ligand as bioinspired structural motif, were investigated. The study includes absorption, emission, resonance Raman and transient absorption spectroscopy in combination with quantum chemical simulations to determine the light‐driven reactivity of the complex. Moreover, spectroelectrochemistry was employed for an in‐depth characterization of the optical properties of the reduced complex. Finally, a photolysis experiment using triethanolamine as electron source, in conjunction with redox titrations, demonstrated that visible light irradiation triggers the formation of the doubly‐reduced singly‐protonated derivative of RuL1, where both redox equivalents are stored on the alloxazine‐based ligand.
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来源期刊
ChemPhotoChem
ChemPhotoChem Chemistry-Physical and Theoretical Chemistry
CiteScore
5.80
自引率
5.40%
发文量
165
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