Improving Photophysical Properties of Deazaflavin Derivatives by Acrylaldehyde Bridging: A Theoretical Investigation

IF 3 4区化学 Q3 CHEMISTRY, PHYSICAL

ChemPhotoChem Pub Date : 2024-06-10 DOI:10.1002/cptc.202400053

Dr. Huimin Guo, Siyu Liu, Dr. Xin Liu, Prof. Dr. Jianzhang Zhao

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Abstract

The electronic structure and photophysical properties of several acrylaldehyde-bridged deazaflavin derivatives (cFLs) were investigated theoretically. The impact of acrylaldehyde bridging on photophysical properties of deazaflavin (cFL) is strongly site-dependent. Specifically, the change of adiabatic energy of electronic transitions(ΔE_ad) and vibronic coupling promote fluorescent emission to be comparable to internal conversion of cFL and cFL4 (both C5−C6 and C9−N10 bridged, but C9−N10 bridged by propene), turning them eligible as fluorescent sensors. As El-Sayed's rule is satisfied in cFL1(C5−C6 bridged), cFL2(C9−N10 bridged) and cFL3(both C5−C6 and C9−N10 bridged), intersystem crossing from first singlet excited state to triplet excited states (T_n) become dominant and the evolution of excited cFLs from T₁ appears vital. The rate constants of photophysical processes indicate these cFLs are of dominantly high steady state T₁ concentration and are potential triplet sensitizers. We expect the findings would pave the way for rational design of novel cFLs with extraordinary photophysical properties.

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通过丙烯醛桥接改善去氮黄素衍生物的光物理特性：理论研究

我们从理论上研究了几种丙烯醛桥接的去氮黄素衍生物（cFLs）的电子结构和光物理性质。丙烯醛桥接对去氮黄素（cFL）光物理性质的影响具有很强的位点依赖性。具体来说，电子跃迁绝热能（ΔEad）和振子耦合的变化促使荧光发射与 cFL 和 cFL4（均为 C5-C6 和 C9-N10 桥接，但 C9-N10 由丙烯桥接）的内部转换相当，从而使它们成为合格的荧光传感器。由于 cFL1（C5-C6 桥接）、cFL2（C9-N10 桥接）和 cFL3（C5-C6 和 C9-N10 桥接）符合 El-Sayed 规则，从第一单激发态到三重激发态（Tn）的系统间交叉成为主导，因此从 T1 开始的激发 cFL 演化显得至关重要。光物理过程的速率常数表明，这些 cFLs 的稳态 T1 浓度很高，是潜在的三重态敏化剂。我们希望这些发现能为合理设计具有非凡光物理性质的新型 cFL 铺平道路。

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来源期刊

ChemPhotoChem Chemistry-Physical and Theoretical Chemistry

CiteScore

5.80

自引率

5.40%

发文量

165