Sung-Eun Suh scite author profile

Site selectivity represents a key challenge for non-directed C−H functionalization, even when the C−H bond is intrinsically reactive. Here, we report a copper-catalyzed method for benzylic C−H azidation of diverse molecules. Experimental and density functional theory studies suggest the benzyl radical reacts with a Cu II -azide species via a radical-polar crossover pathway. Comparison of this method with other C−H azidation methods highlights its unique site selectivity, and conversions of the benzyl azide products into amine, triazole, tetrazole, and pyrrole functional groups highlight the broad utility of this method for target molecule synthesis and medicinal chemistry.

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Radical C(sp3)–H functionalization and cross-coupling reactions

Golden

2022

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Chemical and Electrochemical O₂ Reduction on Earth-Abundant M-N-C Catalysts and Implications for Mediated Electrolysis

et al. 2022

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M-N-C catalysts, incorporating non-precious-metal ions (e.g. M = Fe, Co) within a nitrogen-doped carbon support, have been the focus of broad interest for electrochemical O 2 reduction and aerobic oxidation reactions. The present study explores the mechanistic relationship between the O 2 reduction mechanism under electrochemical and chemical conditions. Chemical O 2 reduction is investigated via the aerobic oxidation of a hydroquinone, in which the O−H bonds supply the protons and electrons needed for O 2 reduction to water. Mechanistic studies have been conducted to elucidate whether the M-N-C catalyst couples two independent half-reactions (IHR), similar to electrode-mediated processes, or mediates a direct inner-sphere reaction (ISR) between O 2 and the organic molecule. Kinetic data support the latter ISR pathway. This conclusion is reinforced by rate/potential correlations that reveal significantly different Tafel slopes, implicating different mechanisms for chemical and electrochemical O 2 reduction.

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Benzylic C–H isocyanation/amine coupling sequence enabling high-throughput synthesis of pharmaceutically relevant ureas

et al. 2021

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Sung-Eun Suh

Site-Selective Copper-Catalyzed Azidation of Benzylic C–H Bonds

Radical C(sp3)–H functionalization and cross-coupling reactions

Chemical and Electrochemical O₂ Reduction on Earth-Abundant M-N-C Catalysts and Implications for Mediated Electrolysis

Benzylic C–H isocyanation/amine coupling sequence enabling high-throughput synthesis of pharmaceutically relevant ureas

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Sung-Eun Suh

Site-Selective Copper-Catalyzed Azidation of Benzylic C–H Bonds

Radical C(sp3)–H functionalization and cross-coupling reactions

Chemical and Electrochemical O2 Reduction on Earth-Abundant M-N-C Catalysts and Implications for Mediated Electrolysis

Benzylic C–H isocyanation/amine coupling sequence enabling high-throughput synthesis of pharmaceutically relevant ureas

Contact Info

Product

Resources

About

Chemical and Electrochemical O₂ Reduction on Earth-Abundant M-N-C Catalysts and Implications for Mediated Electrolysis