Asymmetric, radical C–H functionalizations are rare, yet powerful tools for solving modern synthetic challenges. Specifically, the enantio- and regio-selective C–H amination of alcohols to access medicinally valuable, chiral β-amino alcohols remains elusive. To solve this challenge, a radical relay chaperone strategy was designed, wherein an alcohol is transiently converted to an imidate radical that undergoes intramolecular H-atom transfer (HAT). This regioselective HAT was also rendered enantioselective by harnessing energy transfer catalysis to mediate selective radical generation and interception by a chiral copper catalyst. The successful development of this multi-catalytic, asymmetric, radical C–H amination enables broad access to chiral β-amino alcohols from a variety of alcohols containing alkyl, allyl, benzyl, and propargyl C–H bonds. Mechanistic experiments reveal triplet energy sensitization of a Cu-bound radical precursor facilitates catalyst-mediated HAT stereoselectivity – enabling the synthesis of several important classes of chiral β-amines by enantioselective, radical C–H amination.
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