Merging dual photoredox/cobalt catalysis and boronic acid (derivatives) activation for the Minisci reaction

S. Pillitteri, P. Ranjan, G.M. Ojeda-Carralero, L.V.Y. Amaya, J.E. Alfonso-Ramos, E.V. van der Eycken, U.K. Sharma*

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

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Abstract

The merger of photoredox catalysis and organometallic chemistry has effectively enabled multiple cross-coupling pathways. Here we report a visible-light promoted photoredox-cobalt catalyzed Minisci reaction of N-heteroarenes under mild conditions, employing various boronic acids and derivatives as alkyl radical precursors. This study demonstrates the prominent ability of the Co co-catalyst to promote the oxidation step of the photocatalytic cycle following a reductive quenching pathway, thus avoiding the use of stoichiometric (inorganic) oxidants. This feature enables the straightforward application of photo-flow conditions, particularly attractive for an easy scale-up and to enhance the efficiency of the reaction (throughput: 0.78 mmol center dot h(-1) in flow vs. 0.02 mmol center dot h(-1) in batch). Furthermore, the process is predominantly selective towards the C2-alkylation of quinolines and a mechanistic rationale has been provided with both experimental and DFT calculation support. The developed protocol demonstrates broad applicability for the alkylation of different N-heteroarenes under suitable homogeneous conditions for a flow-compatible Minisci reaction.
Original languageEnglish
Pages (from-to)6958-6967
Number of pages10
JournalOrganic Chemistry Frontiers
Volume9
Issue number24
Early online date1 Nov 2022
DOIs
Publication statusPublished - 6 Dec 2022

Keywords

  • C-H ALKYLATION
  • MOLECULAR-OXYGEN
  • N-HETEROARENES
  • BASE CATALYSIS
  • RADICALS
  • FUNCTIONALIZATION
  • DISTORTION/INTERACTION
  • SUBSTITUTION
  • HETEROCYCLES
  • ARYLATION

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