Many
reactions involving allenyl ion species have been studied,
but reactions involving allenyl radicals are less well understood,
perhaps because of the inconvenience associated with the generation
of short-lived allenyl radicals. We describe here a versatile method
for the generation of allenyl radicals and their previously unreported
applications in the intermolecular 1,4-carbocyanation and 1,4-sulfimidocyanation
of 1,3-enynes. With the assistance of the trifunctional reagents,
alkyl diacyl peroxides or N-fluorobenzenesulfonimide,
a range of synthetically challenging multisubstituted allenes can
be prepared with high regioselectivity. These multisubstituted allenes
can be easily transformed into synthetically useful structures such
as fluorinated vinyl cyanides, lactones, functionalized allenyl amides,
1-aminonaphthalenes, and pyridin-2(1H)-ones, and
several novel transformations are reported. The results of radical
scavenger and radical clock experiments are consistent with the proposed
allenyl radical pathway. Density functional theory (DFT) and IR spectroscopy
studies suggest the formation of an isocyanocopper(II) species in
the ligand exchange step. On the basis of the results of IR, DFT,
and diastereoselectivity studies, an isocyanocopper(II)/copper(I)
catalytic cycle is proposed, which differs from the previously considered
Cu(III) mechanism in cyanation reactions.
Chiral allenes are important structural motifs frequently found in natural products, pharmaceuticals, and other organic compounds. Asymmetric 1,4-difunctionalization of 1,3enynes is a promising strategy to construct axial chirality and produce substituted chiral allenes from achiral substrates. However, the previous state of the art in 1,4-difunctionalization of 1,3-enynes focused on the allenyl anion pathway. Because of this, only electrophiles can be introduced into the allene backbones in the second functionalization step, consequently limiting the reaction and allene product types. The development of asymmetric 1,4difunctionalization of 1,3-enynes via a radical pathway would complement previous methods and support expansion of the toolbox for the synthesis of asymmetric allenes. Herein, we report the first radical enantioselective allene formation via a group transfer pathway in the context of copper-catalyzed radical 1,4-difunctionalization of 1,3-enynes. This method addresses a longstanding unsolved problem in asymmetric radical chemistry, provides an important strategy for stereocontrol with free allenyl radicals, and offers a novel approach to the valuable, but previously inaccessible, chiral allenes. This work should shed light on asymmetric radical reactions and may lead to other enantioselective group transfer reactions.
A copper-catalyzed radical oxycyanation of unactivated alkenes and styrenes to produce beta-cyanohydrin derivatives with the cyano group attached on the more substituted carbon center was reported.
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