微溶剂化的F⁻(H₂O) + CH₃I的S(N)2反应动力学。对溶剂化产物形成受抑制的洞察。

Microsolvated F(-)(H2O) + CH3I S(N)2 Reaction Dynamics. Insight into the Suppressed Formation of Solvated Products.

作者信息

Zhang Jiaxu, Yang Li, Xie Jing, Hase William L

机构信息

Institute of Theoretical and Simulation Chemistry, School of Chemical Engineering and Technology, Harbin Institute of Technology , Harbin 150001, People's Republic of China.

Department of Chemistry, University of Minnesota , Minneapolis, Minnesota 55455, United States.

出版信息

J Phys Chem Lett. 2016 Feb 18;7(4):660-5. doi: 10.1021/acs.jpclett.5b02780. Epub 2016 Feb 1.

DOI:10.1021/acs.jpclett.5b02780

PMID:26821192

Abstract

Microsolvation offers a bottom-up approach to investigate details of how solute-solvent interactions affect chemical reaction dynamics. The dynamics of the microsolvated S(N)2 reaction F(-)(H2O) + CH3I are uncovered in detail by using direct chemical dynamics simulations. Direct rebound and stripping and indirect atomic-level mechanisms are observed. The indirect events comprise ∼70% of the solvated reaction and occur predominantly via a hydrogen-bonded F(-)(H2O)···HCH2I prereaction complex. The reaction dynamics show propensity for the direct three-body dissociation channel F(-)(H2O) + CH3I → CH3F + I(-) + H2O after passing the reaction's dynamical bottleneck. The water molecule leaves the reactive system before traversing the postreaction region of the PES, where water transfer toward the product species occurs. This provides an insight into the very interesting finding of strongly suppressed formation of energetically favored solvated products for almost all SN2 reactions under microsolvation.

摘要

微溶剂化提供了一种自下而上的方法来研究溶质 - 溶剂相互作用如何影响化学反应动力学的细节。通过直接化学动力学模拟详细揭示了微溶剂化的S(N)2反应F(-)(H2O) + CH3I的动力学。观察到直接反弹和剥离以及间接原子水平的机制。间接事件占溶剂化反应的约70%，主要通过氢键结合的F(-)(H2O)···HCH2I预反应复合物发生。反应动力学表明，在通过反应的动力学瓶颈后，直接三体解离通道F(-)(H2O) + CH3I → CH3F + I(-) + H2O具有倾向性。水分子在穿过PES的反应后区域之前离开反应系统，在该区域会发生向产物物种的水转移。这为微溶剂化下几乎所有SN2反应中能量上有利的溶剂化产物形成受到强烈抑制这一非常有趣的发现提供了见解。

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微溶剂化的F⁻(H₂O) + CH₃I的S(N)2反应动力学。对溶剂化产物形成受抑制的洞察。

Microsolvated F(-)(H2O) + CH3I S(N)2 Reaction Dynamics. Insight into the Suppressed Formation of Solvated Products.

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