Phenol Photostatic Spectra and Quantum-Classical Photodynamic Deprotonation

IF 2.3 3区化学 Q3 CHEMISTRY, PHYSICAL International Journal of Quantum Chemistry Pub Date : 2024-10-22 DOI:10.1002/qua.27504

Vladimir Pomogaev, Elena Bocharnikova, Olga Tchaikovskaya, Pavel Avramov

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Abstract

The spectral-luminescence properties and photochemical conversions of phenol were analyzed for an isolated molecule as well as in water solvents in a continuum implicit model and explicit atomistic surroundings. This involved employing cut-edge hybrid quantum-classical methodologies to generate static optical spectra and the excited dissipative crossing potential energy curves. A combination of electronic excitations, gradient calculations, and embedding electrostatic potential fitting charges on quantum-classical molecular dynamic propagation trajectories provided statistically averaged absorption spectra. The mixed-reference spin-flip multiconfigurational linear response method based on reference triplet preprocessed in the time-dependent density-functional theory was utilized to determine conical intersections between the lowest excited and ground states, as well as two-stage transitions from the second excitation to the ground state. Non-adiabatic quantum-classical molecular dynamics defined photodissipative trajectories of excited states, their lifetimes, and crossing points through trajectory surface hopping together with the mixed-reference spin-flip and embedding electrostatic potential fitting approaches. Dyson orbitals of the extended Koopmans' theorem were applied to reveal the nature of molecular states at conical intersections and key points on photodynamic trajectories. Potential hydroxyl group cleavage predicted with conical intersections searching turns to “swift” OH deprotonation through |π→ $σ_{OH}^{*}$ ⟩ transition along photodynamic propagations in contrast with “long” processes leading to benzene ring deformation with stable OH bond.

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苯酚光静态光谱和量子经典光动力去质子化作用

在连续隐式模型和显式原子环境中，分析了孤立分子和水溶液中苯酚的光谱发光特性和光化学转换。这包括采用切边混合量子-经典方法生成静态光学光谱和激发耗散交叉势能曲线。电子激发、梯度计算和量子经典分子动力学传播轨迹上的静电势拟合电荷嵌入相结合，提供了统计平均吸收光谱。混合参考自旋翻转多配置线性响应法基于参考三重在时变密度函数理论中的预处理，用来确定最低激发态和基态之间的锥形交叉，以及从第二激发态到基态的两级转变。非绝热量子经典分子动力学定义了激发态的光耗散轨迹、其寿命，以及通过轨迹面跳跃和混合参考自旋翻转和嵌入静电位拟合方法确定的交叉点。应用扩展库普曼斯定理的戴森轨道揭示了分子状态在锥形交叉点和光动力轨迹关键点的性质。通过|π→ σ OH * $$ {\upsigma}_\{mathrm{OH}}^{\ast }，利用锥形交叉搜索预测的潜在羟基裂解变成了 "迅速 "的 OH 去质子化。$$ ⟩转变沿着光动力传播，与 "长 "过程形成对比，"长 "过程导致苯环变形，OH 键稳定。

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来源期刊

International Journal of Quantum Chemistry 化学-数学跨学科应用

CiteScore

4.70

自引率

4.50%

发文量

185

审稿时长

2 months

期刊介绍： Since its first formulation quantum chemistry has provided the conceptual and terminological framework necessary to understand atoms, molecules and the condensed matter. Over the past decades synergistic advances in the methodological developments, software and hardware have transformed quantum chemistry in a truly interdisciplinary science that has expanded beyond its traditional core of molecular sciences to fields as diverse as chemistry and catalysis, biophysics, nanotechnology and material science.