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

doi:10.1039/d2qo01441f

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 journal › Article › Academic › peer-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 language	English
Pages (from-to)	6958-6967
Number of pages	10
Journal	Organic Chemistry Frontiers
Volume	9
Issue number	24
Early online date	1 Nov 2022
DOIs	https://doi.org/10.1039/d2qo01441f
Publication status	Published - 6 Dec 2022

Keywords

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

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10.1039/d2qo01441f

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

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.",

keywords = "C-H ALKYLATION, MOLECULAR-OXYGEN, N-HETEROARENES, BASE CATALYSIS, RADICALS, FUNCTIONALIZATION, DISTORTION/INTERACTION, SUBSTITUTION, HETEROCYCLES, ARYLATION",

author = "S. Pillitteri and P. Ranjan and G.M. Ojeda-Carralero and L.V.Y. Amaya and J.E. Alfonso-Ramos and \{van der Eycken\}, E.V. and U.K. Sharma",

note = "Funding Information: S. P. (experiments and writing) is thankful to the FWO for obtaining a PhD scholarship (S. P. grant No. 11H0121N). G. M. O. C. is grateful to VLIR-UOS for financial support of a Flemish-Cuba cooperation project (CU2018TEA458A101). The publication has been prepared with the support of the “RUDN University Strategic Academic Leadership Program” (recipient E. V. V. d. E.; writing and supervision). G. M. O. C. and J. E. A. R. are grateful to Ana Lilian Montero-Alejo for her valuable suggestions. J. E. A. R acknowledges CITMA for financial support (project PN223LH010-002), Cuba. Powered@NLHPC: This research was partially supported by the supercomputing infrastructure of the NLHPC (ECM-02), Chile. Publisher Copyright: {\textcopyright} 2022 The Royal Society of Chemistry.",

year = "2022",

month = dec,

day = "6",

doi = "10.1039/d2qo01441f",

language = "English",

volume = "9",

pages = "6958--6967",

journal = "Organic Chemistry Frontiers",

issn = "2052-4110",

publisher = "Royal Society of Chemistry",

number = "24",

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TY - JOUR

T1 - Merging dual photoredox/cobalt catalysis and boronic acid (derivatives) activation for the Minisci reaction

AU - Pillitteri, S.

AU - Ranjan, P.

AU - Ojeda-Carralero, G.M.

AU - Amaya, L.V.Y.

AU - Alfonso-Ramos, J.E.

AU - van der Eycken, E.V.

AU - Sharma, U.K.

N1 - Funding Information: S. P. (experiments and writing) is thankful to the FWO for obtaining a PhD scholarship (S. P. grant No. 11H0121N). G. M. O. C. is grateful to VLIR-UOS for financial support of a Flemish-Cuba cooperation project (CU2018TEA458A101). The publication has been prepared with the support of the “RUDN University Strategic Academic Leadership Program” (recipient E. V. V. d. E.; writing and supervision). G. M. O. C. and J. E. A. R. are grateful to Ana Lilian Montero-Alejo for her valuable suggestions. J. E. A. R acknowledges CITMA for financial support (project PN223LH010-002), Cuba. Powered@NLHPC: This research was partially supported by the supercomputing infrastructure of the NLHPC (ECM-02), Chile. Publisher Copyright: © 2022 The Royal Society of Chemistry.

PY - 2022/12/6

Y1 - 2022/12/6

N2 - 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.

AB - 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.

KW - C-H ALKYLATION

KW - MOLECULAR-OXYGEN

KW - N-HETEROARENES

KW - BASE CATALYSIS

KW - RADICALS

KW - FUNCTIONALIZATION

KW - DISTORTION/INTERACTION

KW - SUBSTITUTION

KW - HETEROCYCLES

KW - ARYLATION

U2 - 10.1039/d2qo01441f

DO - 10.1039/d2qo01441f

M3 - Article

SN - 2052-4110

VL - 9

SP - 6958

EP - 6967

JO - Organic Chemistry Frontiers

JF - Organic Chemistry Frontiers

IS - 24

ER -

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

Abstract

Keywords

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