Reaction mechanism of acetonitrile, olefins, and amines catalyzed by Ag2CO3: A DFT investigation

IF 1.9 4区化学 Q2 CHEMISTRY, ORGANIC

Journal of Physical Organic Chemistry Pub Date : 2023-12-27 DOI:10.1002/poc.4594

Bin Chen, Da-Gang Zhou, Li-Jun Yang

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Abstract

The mechanism of Ag₂CO₃-catalyzed reactions of acetonitrile, olefins, and amines was investigated by using the M06-L-D3/6-311 + G(d,p) method and level, and solvation model based on solute electron density (SMD) model was applied to simulate the solvent effect. Calculations show that the Ag₂CO₃ could achieve the Csp³-H activation by coordinating with the terminal nitrogen atom of CH₃CN; then, the addition reaction happened between the obtained Ag-complex intermediate and olefin via the coordination of Ag and benzene ring; finally, the obtained radical intermediate continues to go through one single electron transfer (SET) process, addition reaction, and H-shift reaction to yield the final product. The computational results reveal that Fe³⁺ cation would have assisted the SET process successfully and the path of direct addition with the amine is the optimal. Fukui function and dual descriptor can be used to predict the reactive sites, and electron spin density isosurface graphs can analyze the structures and reveal the substances.

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Ag2CO3 催化乙腈、烯烃和胺的反应机理：DFT 研究

采用M06-L-D3/6-311 + G(d,p)方法和水平研究了Ag2CO3催化乙腈、烯烃和胺反应的机理，并应用基于溶质电子密度（SMD）模型的溶解模型模拟了溶剂效应。计算结果表明，Ag2CO3 可通过与 CH3CN 的末端氮原子配位实现 Csp3-H 活化；然后，通过 Ag 与苯环的配位，得到的 Ag 复合物中间体与烯烃发生加成反应；最后，得到的自由基中间体继续经历一次单电子转移（SET）过程、加成反应和 H 移位反应，得到最终产物。计算结果表明，Fe3+ 阳离子可以成功地协助 SET 过程，而与胺直接加成的路径是最佳的。福井函数和双重描述符可用于预测反应位点，电子自旋密度等值面图可分析结构并揭示物质。

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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来源期刊

Journal of Physical Organic Chemistry 化学-物理化学

CiteScore

3.60

自引率

11.10%

发文量

161

审稿时长

2.3 months

期刊介绍： The Journal of Physical Organic Chemistry is the foremost international journal devoted to the relationship between molecular structure and chemical reactivity in organic systems. It publishes Research Articles, Reviews and Mini Reviews based on research striving to understand the principles governing chemical structures in relation to activity and transformation with physical and mathematical rigor, using results derived from experimental and computational methods. Physical Organic Chemistry is a central and fundamental field with multiple applications in fields such as molecular recognition, supramolecular chemistry, catalysis, photochemistry, biological and material sciences, nanotechnology and surface science.