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Literature DB >> 35377635

Why the Photochemical Reaction of Phenol Becomes Ultrafast at the Air-Water Interface: The Effect of Surface Hydration.

Tatsuya Ishiyama¹, Tahei Tahara^2,3, Akihiro Morita^4,5.

Abstract

Photochemical reactions at the air-water interface can show remarkably different rates from those in bulk water. The present study elucidates the reaction mechanism of phenol characteristic at the air-water interface by the combination of molecular dynamics simulation and quantum chemical calculations of the excited states. We found that incomplete hydrogen bonding to phenol at the air-water interface affects excited states associated with the conical intersection and significantly reduces the reaction barrier, resulting in the distinctively facilitated rate in comparison with the bulk phase. The present study indicates that the reaction dynamics can be substantially different at the interfaces in general, reflecting the difference in the stabilization energy of the electronic states in markedly different solvation at the interface.

Entities: Chemical

Mesh：

Substances：
Water
Phenol

Year: 2022 PMID： 35377635 PMCID： PMC9012180 DOI： 10.1021/jacs.1c13336

Source DB: PubMed Journal: J Am Chem Soc ISSN： 0002-7863 Impact factor: 15.419

26 in total

1. Time-dependent quantum wave-packet description of the 1pi sigma* photochemistry of phenol.

Authors: Zhenggang Lan; Wolfgang Domcke; Valérie Vallet; Andrzej L Sobolewski; Susanta Mahapatra
Journal: J Chem Phys Date: 2005-06-08 Impact factor: 3.488

2. Combined Monte Carlo and quantum mechanics study of the solvatochromism of phenol in water. The origin of the blue shift of the lowest pi-pi* transition.

Authors: Rafael C Barreto; Kaline Coutinho; Herbert C Georg; Sylvio Canuto
Journal: Phys Chem Chem Phys Date: 2009-01-15 Impact factor: 3.676

3. Exploring the time-scales of H-atom detachment from photoexcited phenol-h(6) and phenol-d(5): statistical vs nonstatistical decay.

Authors: Azhar Iqbal; Michelle S Y Cheung; Michael G D Nix; Vasilios G Stavros
Journal: J Phys Chem A Date: 2009-07-23 Impact factor: 2.781

4. Nonadiabatic Tunneling in Photodissociation of Phenol.

Authors: Changjian Xie; Jianyi Ma; Xiaolei Zhu; David R Yarkony; Daiqian Xie; Hua Guo
Journal: J Am Chem Soc Date: 2016-06-17 Impact factor: 15.419

5. Photoinduced Oxidation Reactions at the Air-Water Interface.

Authors: Josep M Anglada; Marilia T C Martins-Costa; Joseph S Francisco; Manuel F Ruiz-López
Journal: J Am Chem Soc Date: 2020-09-08 Impact factor: 15.419

6. The role of pisigma* excited states in the photodissociation of heteroaromatic molecules.

Authors: M N R Ashfold; B Cronin; A L Devine; R N Dixon; M G D Nix
Journal: Science Date: 2006-06-16 Impact factor: 47.728

7. Unravelling the Role of an Aqueous Environment on the Electronic Structure and Ionization of Phenol Using Photoelectron Spectroscopy.

Authors: Jamie W Riley; Bingxing Wang; Joanne L Woodhouse; Mariana Assmann; Graham A Worth; Helen H Fielding
Journal: J Phys Chem Lett Date: 2018-01-26 Impact factor: 6.475

Why the Photochemical Reaction of Phenol Becomes Ultrafast at the Air-Water Interface: The Effect of Surface Hydration.

1. Time-dependent quantum wave-packet description of the 1pi sigma* photochemistry of phenol.

2. Combined Monte Carlo and quantum mechanics study of the solvatochromism of phenol in water. The origin of the blue shift of the lowest pi-pi* transition.

3. Exploring the time-scales of H-atom detachment from photoexcited phenol-h(6) and phenol-d(5): statistical vs nonstatistical decay.

4. Nonadiabatic Tunneling in Photodissociation of Phenol.

5. Photoinduced Oxidation Reactions at the Air-Water Interface.

6. The role of pisigma* excited states in the photodissociation of heteroaromatic molecules.

7. Unravelling the Role of an Aqueous Environment on the Electronic Structure and Ionization of Phenol Using Photoelectron Spectroscopy.

8. Dynamics at conical intersections: the influence of O-H stretching vibrations on the photodissociation of phenol.

9. Atmospheric photochemistry at a fatty acid-coated air-water interface.

10. The photochemical reaction of phenol becomes ultrafast at the air-water interface.

1. Photooxidation of the Phenolate Anion is Accelerated at the Water/Air Interface.