Combined multi-level quantum mechanics theories and molecular mechanics study of water-induced transition state of OH^- + CO2 reaction in aqueous solution

The presence of a solvent interacting with a system brings about qualitative changes from the corresponding gas-phase reactions. A solvent can not only change the energetics along the reaction pathway, but also radically alter the reaction mechanism. Here, we investigated the water-induced transitio...

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Published in中国物理B:英文版 Vol. 26; no. 10; pp. 200 - 204
Main Author 李琛 牛美兴 刘鹏 李永方 王敦友
Format Journal Article
LanguageEnglish
Published 01.10.2017
Subjects
CCSD(T)
CO2
分子力学方法
多组分
气相反应
水溶液
过渡态
量子力学理论
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ISSN1674-1056
2058-3834
DOI10.1088/1674-1056/26/10/103401

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Summary:The presence of a solvent interacting with a system brings about qualitative changes from the corresponding gas-phase reactions. A solvent can not only change the energetics along the reaction pathway, but also radically alter the reaction mechanism. Here, we investigated the water-induced transition state of the OH^-+CO2→HCO3^- reaction using a multi-level quantum mechanics and molecular mechanics method with an explicit water model. The solvent energy contribution along the reaction pathway has a maximum value which induces the highest energy point on the potential of mean force. The charge transfer from OH^- to CO2 results in the breaking of the OH^- solvation shell and the forming of the CO2 solvation shell. The loss of hydrogen bonds in the OH^- solvation shell without being compensated by the formation of hydrogen bonds in the CO2 solvation shell induces the transition state in the aqueous solution. The calculated free energy reaction barrier at the CCSD(T)/MM level of theory, 11.8 kcal/mol, agrees very well with the experimental value, 12.1 kcal/mol.
Bibliography:Chen Li, Meixing Niu, Peng Liu, Yongfang Li, Dunyou Wang( College of Physics and Electronics, Shandong Normal University, Ji'nan 250014, China)
The presence of a solvent interacting with a system brings about qualitative changes from the corresponding gas-phase reactions. A solvent can not only change the energetics along the reaction pathway, but also radically alter the reaction mechanism. Here, we investigated the water-induced transition state of the OH^-+CO2→HCO3^- reaction using a multi-level quantum mechanics and molecular mechanics method with an explicit water model. The solvent energy contribution along the reaction pathway has a maximum value which induces the highest energy point on the potential of mean force. The charge transfer from OH^- to CO2 results in the breaking of the OH^- solvation shell and the forming of the CO2 solvation shell. The loss of hydrogen bonds in the OH^- solvation shell without being compensated by the formation of hydrogen bonds in the CO2 solvation shell induces the transition state in the aqueous solution. The calculated free energy reaction barrier at the CCSD(T)/MM level of theory, 11.8 kcal/mol, agrees very well with the experimental value, 12.1 kcal/mol.
11-5639/O4
transition state, reaction pathway, free energy barrier, solvent effect
ISSN:1674-1056
2058-3834
DOI:10.1088/1674-1056/26/10/103401