用从头算分子动力学揭示F - + ch3cl→Cl - + ch3f反应的新机制特征

Yongfan Wang
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引用次数: 0

摘要

SN2反应因其在生物分子化学和有机化学中的重要作用而受到广泛关注。在过去的几十年里,大量的论文对SN2反应的机理的认识取得了很大的进展。然而,如果没有精确的势能面,反应的原子细节是复杂的,很难探索。在本报告中,从头算分子动力学方法揭示了反应的探索。虽然势能面是残缺的,但我们仍然可以对机理的研究做出贡献。本文在F−+CH3Cl→Cl−+CH3F中发现了一种新的机制,该机制与抽象机制具有共同的过渡态,但避免了质子转移通道。它是质子回旋与经典背侧攻击机制的结合,这是以往文献中从未观察到的。有趣的是,在这种新机制中存在一个同时涉及C-H-F和Cl-H-F氢键的氢键转移过程。这为质子在低碰撞能量下的转移提供了另一条通道,表明尽管已有各种SN2反应机理的报道,但仍需进行更多的探索。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Revealing a new mechanism feature of F ⁻ +CH 3 Cl→Cl ⁻ +CH 3 F reaction by using ab initio molecular dynamics
SN2 reaction gained much attention because of its vital role in biomolecular and organic chemistry. In the past decades, great progress on mechanism understanding of SN2 reaction has been made by a lot of papers. However, atomic details of the reaction are complicated and hard to explore without precise potential energy surface. In this report, an ab initio molecular dynamics method shed light on the reaction explorations. Although a potential energy surface is disable, we can still make contributions on the mechanism study. Here, we found a novel mechanism in F−+CH3Cl→Cl−+CH3F that shared common transition state with abstract mechanism but avoid the proton transfer channel. It is a combination of proton roundabout and classical back-side attack mechanism, which is never observed in previous papers. Interestingly, a hydrogen bond transfer process exists in the novel mechanism which simultaneously involved in both C-H-F and Cl-H-F hydrogen bond. It provides another channel of proton transfer in low collision energy, and shows that more explorations have to be carried out even though various mechanism of SN2 reaction have been reported.
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来源期刊
Journal of Atomic and Molecular Sciences
Journal of Atomic and Molecular Sciences PHYSICS, ATOMIC, MOLECULAR & CHEMICAL-
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