Mechanism and origins of regioselectivity of selenium-catalyzed allylic amination reactions†

Organic chemistry frontiers : an international journal of organic chemistry Pub Date : 2024-11-19 Epub Date: 2024-11-05 DOI:10.1039/d4qo01794c

Xiaoxiao Hu , Dengmengfei Xiao , Yu Chen , Yi Lu , Zhihan Zhang , Peiyuan Yu

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Abstract

The mechanism of selenium-catalyzed allylic amination reactions with different ligands has been explored using density functional theory calculations. The mechanism consists of the generation of the key active catalyst selenium bis(imide), an ene reaction, a [2,3]-sigmatropic shift, and ligand-assisted hydrogen transfer. The ene reaction step plays a critical role in determining the regioselectivity of the reaction. Under two different catalytic conditions (Cy₃PSe and IMeSe), OPCy₃ and OIMe were identified as the most optimal ligands. The computational results indicate that the ene reaction does not occur through a simultaneous ligand dissociation process but rather proceeds in a stepwise manner where the ligand dissociates before engaging in the ene reaction with the substrate. Furthermore, the regioselectivity mainly originates from the orbital interaction for acyclic trisubstituted alkenes and the distortion energy for cyclic trisubstituted alkenes.

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硒催化烯丙基氨基化反应的区域选择性机理和起源

通过密度泛函理论计算，探索了硒催化烯丙基胺化反应与不同配体的机理。该机理包括关键活性催化剂硒双亚胺的生成、烯化反应、[2,3]-位移和配体辅助氢转移。烯反应步骤在决定反应的区域选择性方面起着关键作用。在两种不同的催化条件（Cy3PSe 和 IMeSe）下，OPCy3 和 OIMe 被确定为最佳配体。计算结果表明，烯化反应不是通过配体同时解离的过程发生的，而是以逐步进行的方式进行的，即配体先解离，然后再与底物发生烯化反应。此外，非环三取代烯烃的区域选择性主要源于轨道相互作用，而环三取代烯烃的区域选择性主要源于畸变能。

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Organic chemistry frontiers : an international journal of organic chemistry

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7.80

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