A general strategy for C(sp3)\u2013H functionalization with nucleophiles using methyl radical as a hydrogen atom abstractor

Isabelle Nathalie-Marie Leibler,Abigail G Doyle,Makeda A Tekle-Smith

doi:10.1038/s41467-021-27165-z

Isabelle Nathalie-Marie Leibler, Abigail G Doyle + Show 1 more

Open Access

https://doi.org/10.1038/s41467-021-27165-z

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Abstract

Photoredox catalysis has provided many approaches to C(sp3)–H functionalization that enable selective oxidation and C(sp3)–C bond formation via the intermediacy of a carbon-centered radical. While highly enabling, functionalization of the carbon-centered radical is largely mediated by electrophilic reagents. Notably, nucleophilic reagents represent an abundant and practical reagent class, motivating the interest in developing a general C(sp3)–H functionalization strategy with nucleophiles. Here we describe a strategy that transforms C(sp3)–H bonds into carbocations via sequential hydrogen atom transfer (HAT) and oxidative radical-polar crossover. The resulting carbocation is functionalized by a variety of nucleophiles—including halides, water, alcohols, thiols, an electron-rich arene, and an azide—to effect diverse bond formations. Mechanistic studies indicate that HAT is mediated by methyl radical—a previously unexplored HAT agent with differing polarity to many of those used in photoredox catalysis—enabling new site-selectivity for late-stage C(sp3)–H functionalization.

Highlights

Photoredox catalysis has provided many approaches to C(sp3)–H functionalization that enable selective oxidation and C(sp3)–C bond formation via the intermediacy of a carboncentered radical
To evaluate the feasibility of the HATORPC strategy for C(sp3)–H fluorination, we investigated the conversion of diphenylmethane to fluorodiphenylmethane (2)
We focused on N-acyloxyphthalimides and N-alkoxyphthalimides, as these redox-active species deliver a radical hydrogen atom transfer (HAT)

Summary

Introduction

Photoredox catalysis has provided many approaches to C(sp3)–H functionalization that enable selective oxidation and C(sp3)–C bond formation via the intermediacy of a carboncentered radical. Optimization of the HAT precursor focused on three design elements: (1) redox compatibility, (2) bond dissociation energy (BDE) of the radical generated upon fragmentation (favorable thermodynamics), and (3) nucleophilicity of the HAT byproduct (competitive carbocation functionalization).

Results

Conclusion