Control of enantioselectivity in radical reactions was a formidable challenge for organic chemists for decades. Thanks to the key role of transition metal complexes both in promoting and highly enantioselectively cont...Control of enantioselectivity in radical reactions was a formidable challenge for organic chemists for decades. Thanks to the key role of transition metal complexes both in promoting and highly enantioselectively controlling sophisticated synthetic routes, great improvements in this filed have been achieved by merging transition-metal asymmetric catalysis with radical chemistry. Herein we provide a perspective of some of the most significant contributions in the field during the past decades. Accordingly, the major advances are classified based on different strategies for controlling stereoselectivity including: (1) chiral metal complex chelation, (2) chiral metal complex combined with radical species and reductive elimination, (3) chiral metal complex outer-sphere substitution by radical intermediate. Brief discussion of mechanism is presented whenever relevant.展开更多
Due to the significance of corresponding products,enantioselective borylative cyclization reactions have been studied intensively in recent years.Many groups have developed efficient methods to transform unsaturated s...Due to the significance of corresponding products,enantioselective borylative cyclization reactions have been studied intensively in recent years.Many groups have developed efficient methods to transform unsaturated system into asymmetric cyclic organoboron compounds with the ring-size range from three-membered to six-membered in general.Notably,in some cases,fused rings which contain more than two contiguous chiral centers could be obtained by this kind of strategies.This review summarized and reviewed the recent advances in this field and classified these work according to the species of metal catalysts.展开更多
Enantioselective radical desymmetrization is a highly effective approach for rapidly creating enantioenriched molecules,introducing dramatically increased structural complexity from readily available prochiral or meso...Enantioselective radical desymmetrization is a highly effective approach for rapidly creating enantioenriched molecules,introducing dramatically increased structural complexity from readily available prochiral or meso compound feedstocks.Two strategic modes have been developed for these reactions,which differ in the nature of the stereo-determining steps.The first category deals primarily with the stereoselective desymmetrization of closed-shell radical precursors or functional reagents,whereas the second category achieves desymmetrization by stereoselectively functionalizing open-shell radical species.This mini-review explores the research progress in this growing field,aiming to elucidate mechanistic scenarios related to stereochemical control.Additionally,it offers insights into the challenges and opportunities that lie ahead for further development.展开更多
基金Acknowledgement Financial support from the "1000-Youth Talents Plan" and the National Natural Science Foundation of China (No. 21702149)is greatly appreciated.
文摘Control of enantioselectivity in radical reactions was a formidable challenge for organic chemists for decades. Thanks to the key role of transition metal complexes both in promoting and highly enantioselectively controlling sophisticated synthetic routes, great improvements in this filed have been achieved by merging transition-metal asymmetric catalysis with radical chemistry. Herein we provide a perspective of some of the most significant contributions in the field during the past decades. Accordingly, the major advances are classified based on different strategies for controlling stereoselectivity including: (1) chiral metal complex chelation, (2) chiral metal complex combined with radical species and reductive elimination, (3) chiral metal complex outer-sphere substitution by radical intermediate. Brief discussion of mechanism is presented whenever relevant.
基金Financial support from Tianjin University and the National Natural Science Foundation of China(No.21801181)is acknowledged.
文摘Due to the significance of corresponding products,enantioselective borylative cyclization reactions have been studied intensively in recent years.Many groups have developed efficient methods to transform unsaturated system into asymmetric cyclic organoboron compounds with the ring-size range from three-membered to six-membered in general.Notably,in some cases,fused rings which contain more than two contiguous chiral centers could be obtained by this kind of strategies.This review summarized and reviewed the recent advances in this field and classified these work according to the species of metal catalysts.
基金Financial support from the National Natural Science Foundation of China (grant nos.22025103,92256301,21831002,22271133,22101122,and 22201127)the National Key R&D Program of China (grant nos.2021YFF0701604 and 2021YFF0701704)+1 种基金New Cornerstone Science Foundation through the XPLORER PRIZE,Shenzhen Science and Technology Program (grant nos.KQTD20210811090112004 and JCYJ20220818100600001)Shenzhen Key Laboratory of Cross-Coupling Reactions (grant no.ZDSYS20220328104200001).
文摘Enantioselective radical desymmetrization is a highly effective approach for rapidly creating enantioenriched molecules,introducing dramatically increased structural complexity from readily available prochiral or meso compound feedstocks.Two strategic modes have been developed for these reactions,which differ in the nature of the stereo-determining steps.The first category deals primarily with the stereoselective desymmetrization of closed-shell radical precursors or functional reagents,whereas the second category achieves desymmetrization by stereoselectively functionalizing open-shell radical species.This mini-review explores the research progress in this growing field,aiming to elucidate mechanistic scenarios related to stereochemical control.Additionally,it offers insights into the challenges and opportunities that lie ahead for further development.