质子转移后 O-硝基苯酚的激发态衰变和光解。二: 微溶解大气环境中的理论研究。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-31 Epub Date: 2024-10-17 DOI:10.1021/acs.jpca.4c04892
Bo-Wen Yin, Jie-Lei Wang, Jia-Ling Dai, Ji-Wen Jian, Pei-Ke Jia, Ganglong Cui, Bin-Bin Xie
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引用次数: 0

摘要

大气湿度的变化会影响邻硝基苯酚(ONP)周围水分子的数量,从而产生各向异性的化学环境。这反过来又影响了邻硝基苯酚的光动力行为,与气相和溶液中观察到的光动力行为不同。最近,我们利用 MS-CASPT2//CASSCF 方法探索了 ONP 在微溶解环境中质子转移前的激发态衰变和羟基(OH)自由基的生成。众所周知,ONP 能够通过激发态分子内质子转移(ESIPT)过程转化为其酰基硝基异构体(aciONP)。在本研究中,我们使用相同的计算模型研究了aciONP 的光诱导动力学,它可以生成 OH 自由基和亚硝酸(HONO)。我们的计算表明,水分子数量的增加会影响分子几何结构,尤其是 HONO 基团的关键键长和二面角,同时也会降低最小值和交叉点的相对能量。此外,我们还发现了两种不同类型的最小结构:一种是保留分子内氢键的结构,另一种是氢键断裂,H 原子向外翻转的结构。与前一种结构相比,后一种结构具有不同的电子状态特征,有利于体系间的交叉过程。随后提出了两种主要的激发态衰变路径:(PATH I)ESIPT → S1 → S1S0 → S0;(PATH II)ESIPT → S1 → S1-2 → S1T1 → T1 → S0T1 → S0。此外,T1 状态的寿命相对较长,可以形成 OH 自由基和 HONO,而且随着水分子数量的增加,相应的能障也会降低。这些理论发现为研究微溶解大气环境中 aciONP 的光动力学提供了宝贵的见解。
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Excited-State Decay and Photolysis of O-Nitrophenol after Proton Transfer. II: A Theoretical Investigation in the Microsolvated Atmospheric Environment.

Changes in atmospheric humidity affect the number of water molecules surrounding o-nitrophenol (ONP), creating an anisotropic chemical environment. It, in turn, influences the photodynamic behaviors of ONP, differing from those observed in the gas phase and in solution. Recently, we explored the excited-state decay and the generation of the hydroxyl (OH) radical before proton transfer of ONP in the microsolvated environment using the MS-CASPT2//CASSCF approach. As is well known, ONP is capable of converting to its aci-nitro isomer (aciONP) via an excited-state intramolecular proton transfer (ESIPT) process. In the present work, the photoinduced dynamics of aciONP, which can lead to an OH radical and nitrous acid (HONO), was studied using the same computational model. Our calculations demonstrated that increasing the number of water molecules affects the molecular geometries, particularly the key bond lengths and dihedral angles of the HONO group, while also reducing the relative energies of minima and intersections. Moreover, we identified two distinct types of minimum structures: one that retains the intramolecular hydrogen bond and the other that breaks the hydrogen bond with the H atom flipping outward. The latter structure, compared with the former, has a different electronic-state character and facilitates intersystem crossing processes. Subsequently, two major excited-state decay paths were proposed: (PATH I) ESIPT → S1 → S1S0 → S0; (PATH II) ESIPT → S1 → S1-2 → S1T1 → T1 → S0T1 → S0. Furthermore, the T1 state has a relatively long lifetime, allowing for the formation of the OH radical and HONO, and the corresponding energy barriers decrease as the number of water molecules increases. These theoretical findings provide valuable insights into the photodynamics of aciONP in the microsolvated atmospheric environment.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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