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Carbonyl-Directed Aliphatic Fluorination: A Special Type of Hydrogen Atom Transfer Beats Out Norrish II

Fereshte Ghorbani, Stefan Andrew Harry, Joseph N. Capilato, Cody Ross Pitts, Jacob Joram, Garvin N. Peters, John D. Tovar, Ivor Smajlagic, Maxime A. Siegler, Travis Dudding, Thomas Lectka

2020Journal of the American Chemical Society56 citationsDOI

Abstract

Recently, our group reported that enone and ketone functional groups, upon photoexcitation, can direct site-selective sp3 C–H fluorination in terpenoid derivatives. How this transformation actually occurred remained mysterious, as a significant number of mechanistic possibilities came to mind. Herein, we report a comprehensive study describing the reaction mechanism through kinetic studies, isotope-labeling experiments, 19F NMR, electrochemical studies, synthetic probes, and computational experiments. To our surprise, the mechanism suggests intermolecular hydrogen atom transfer (HAT) chemistry is at play, rather than classical Norrish hydrogen atom abstraction as initially conceived. What is more, we discovered a unique role for photopromoters such as benzil and related compounds that necessitates their chemical transformation through fluorination in order to be effective. Our findings provide documentation of an unusual form of directed HAT and are of crucial importance for defining the necessary parameters for the development of future methods.

Topics & Concepts

ChemistryKetoneHydrogen atomHydrogen atom abstractionEnonePhotoexcitationIntermolecular forcePhotochemistryComputational chemistryHydrogenStereochemistryGroup (periodic table)Organic chemistryMoleculeExcited statePhysicsNuclear physicsRadical Photochemical ReactionsFluorine in Organic ChemistryCatalytic C–H Functionalization Methods
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