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关于激发态质子转移光酸及其未来挑战的实验与理论双重视角。

A dual experimental-theoretical perspective on ESPT photoacids and their challenges ahead.

作者信息

Sülzner Niklas, Jung Gregor, Nuernberger Patrick

机构信息

Lehrstuhl für Theoretische Chemie, Ruhr-Universität Bochum 44780 Bochum Germany

Biophysikalische Chemie, Universität des Saarlandes 66123 Saarbrücken Germany

出版信息

Chem Sci. 2024 Dec 2;16(4):1560-1596. doi: 10.1039/d4sc07148d. eCollection 2025 Jan 22.

DOI:10.1039/d4sc07148d
PMID:39759939
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11697080/
Abstract

Photoacids undergo an increase in acidity upon electronic excitation, enabling excited-state proton transfer (ESPT) reactions. A multitude of compounds that allow ESPT has been identified and integrated in numerous applications, as is outlined by reviewing the rich history of photoacid research reaching back more than 90 years. In particular, achievements together with ambitions and challenges are highlighted from a combined experimental and theoretical perspective. Besides explicating the spectral signatures, transient ion-pair species, and electronic states involved in an ESPT, special emphasis is put on the diversity of methods used for studying photoacids as well as on the effects of the environment on the ESPT, illustrated in detail for 8-hydroxypyrene-1,3,6-trisulfonate (HPTS) and the naphthols as examples of prototypical photoacids. The development of exceptionally acidic super-photoacids and magic photoacids is subsequently discussed, which opens the way to applications even in aprotic solvents and provides additional insight into the mechanisms underlying ESPT. In the overview of highlights from theory, a comprehensive picture of the scope of studies on HPTS is presented, along with the general conceptualization of the electronic structure of photoacids and approaches for the quantification of excited-state acidity. We conclude with a juxtaposition of established applications of photoacids together with potential open questions and prospective research directions.

摘要

光酸在电子激发时酸度会增加,从而能够发生激发态质子转移(ESPT)反应。回顾90多年来丰富的光酸研究历史可知,已鉴定出多种能够发生ESPT的化合物,并将其应用于众多领域。特别是,从实验和理论相结合的角度突出了相关成果、抱负和挑战。除了阐述ESPT中涉及的光谱特征、瞬态离子对物种和电子态外,还特别强调了用于研究光酸的方法的多样性以及环境对ESPT的影响,并以8-羟基芘-1,3,6-三磺酸盐(HPTS)和萘酚作为典型光酸的例子进行了详细说明。随后讨论了超强酸性超光酸和神奇光酸的发展,这为甚至在非质子溶剂中的应用开辟了道路,并为ESPT的潜在机制提供了更多见解。在理论亮点概述中,展示了关于HPTS研究范围的全面图景,以及光酸电子结构的一般概念化和激发态酸度量化方法。我们最后并列介绍了光酸的既定应用以及潜在的未解决问题和未来研究方向。

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