CuAAC反应机理:在醋酸和非质子条件下

Cihan Özen, Nurcan Şenyurt Tüzün
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引用次数: 12

摘要

铜-三唑烷的质子化反应是CuAAC反应中一个独特的和最后的环节,它具有重要的动力学意义,甚至可以影响产物的分布。在本研究背景下,通过量子力学计算对铜三唑烷的质子化机理进行了研究,以期对其机理有更深入的了解。在非质子条件下,炔被认为是质子供体,本研究进行的DFT计算的关键发现是质子化步骤的活化能势垒大于环加成步骤。在没有强质子供体的情况下,催化循环中最后的质子化步骤与炔去质子化步骤耦合,从而减慢反应速度。在实验和计算研究的基础上,寻求醋酸促进CuAAC反应的可行途径。以乙酸酯为配体的环加成反应是一个很容易发生的反应,能量学表明它加快了环加成的速度。醋酸在CuAAC反应中为催化循环的最后一个质子化步骤提供质子,在最后一个步骤中作为强质子供体使质子化/去质子化步骤解耦,促进质子化。本文给出的能量学与实验中在醋酸存在下得到的非质子条件下的速率决定步骤和缩短反应时间的实验建议一致。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Mechanism of CuAAC reaction: In acetic acid and aprotic conditions

Protonation of copper-triazolide is a distinctive and final part in CuAAC reaction which has kinetic importance such that it can even affect the product distribution. In the context of this study, the protonation mechanism of copper-triazolide was investigated with quantum mechanical calculations to have a deeper understanding of the mechanism. In aprotic conditions where the alkyne is considered as proton donor, the key finding of DFT calculations performed in this study is that the activation energy barrier for the protonation step is greater than the cycloaddition step. In the absence of a strong proton donor the final protonation step is coupled with the alkyne deprotonation step in the catalytic cycle, which slows down the reaction. A conceivable pathway for acetic acid promoted CuAAC reaction on the basis of experimental and computational studies was also sought. With acetate as ligand, cycloaddition is a facile reaction and the energetics shows that it speeds up the cycloaddition step. Acetic acid in CuAAC reaction provides proton for the final protonation step in the catalytic cycle, decouples the protonation/deprotonation step by acting as a strong proton donor in the last step and facilitates protonation. The energetics presented herein are in accordance with the experimental proposals on rate-determining step in aprotic conditions and decreased reaction times obtained in the experiments in the presence of acetic acid.

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期刊介绍: The Journal of Molecular Catalysis A: Chemical publishes original, rigorous, and scholarly full papers that examine the molecular and atomic aspects of catalytic activation and reaction mechanisms in homogeneous catalysis, heterogeneous catalysis (including supported organometallic catalysis), and computational catalysis.
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