分子内力
荧光团
取代基
光化学
化学
氢键
荧光
激发态
分子
质子
计算化学
基态
红外线的
势能
费斯特共振能量转移
含时密度泛函理论
分子几何学
部分
斯托克斯位移
作者
Jianxing Song,Qin Ding,Ken Deng,Ping‐Ping Sun,Zeyuan Tang,Chaoyuan Zeng,Weijie Chi
摘要
Molecules that exhibit excited-state intramolecular proton transfer (ESIPT) have demonstrated great promise in fluorescent probes. The electronic effect of substituents has an important influence on the ESIPT process. In this study, we investigated the effects of substituents on the ESIPT mechanism and the photophysical behavior of single-benzene fluorophore (SBF) derivatives with computational chemistry methods. The ω-B97XD/TZVP level of theory was used to calculate bond lengths, interaction energies, infrared spectra, electron-hole analysis, and the energy barriers of ESIPT in SBFs. Our results confirmed the presence of intramolecular hydrogen bonds in both the ground and excited states in SBFs. Transition state calculation demonstrated that increasing the number of electron-withdrawing groups enhances hydrogen bonding interaction and facilitates ESIPT. However, excessive substitution saturates the electron-withdrawing effect, suppresses C═O basicity, and potentially induces conformational constraints, leading to a higher barrier. Our findings provide some important theoretical basis for the design of ESIPT fluorescent dyes.
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