光氧化还原催化下亚芳基丙二酸酯的还原芳基化反应
Reductive Arylation of Arylidene Malonates Using Photoredox Catalysis.
作者信息
Betori Rick C, Scheidt Karl A
机构信息
Department of Chemistry, Center for Molecular Innovation and Drug Discovery, Northwestern University, 2145 Sheridan Road, Evanston, Illinois 60208, United States.
出版信息
ACS Catal. 2019 Nov 1;9(11):10350-10357. doi: 10.1021/acscatal.9b03608. Epub 2019 Oct 17.
Abstract
A strategy with arylidene malonates provides access to -umpolung single-electron species. Reported here is the utilization of these operators in intermolecular radical-radical arylations, while avoiding conjugate addition/dimerization reactivity that is commonly encountered in enone-based photoredox chemistry. This reactivity relies on tertiary amines that serve to both activate the arylidene malonate for single-electron reduction by a proton-coupled electron transfer mechanism as well as serve as a terminal reductant. This photoredox catalysis pathway demonstrates the versatility of stabilized radicals for unique bond-forming reactions.
摘要
一种使用亚芳基丙二酸酯的策略能够得到极性反转的单电子物种。本文报道了这些试剂在分子间自由基-自由基芳基化反应中的应用,同时避免了烯酮基光氧化还原化学中常见的共轭加成/二聚反应活性。这种反应活性依赖于叔胺,叔胺既能通过质子耦合电子转移机制活化亚芳基丙二酸酯以进行单电子还原,又能作为终端还原剂。这种光氧化还原催化途径证明了稳定自由基在独特的成键反应中的多功能性。
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