Electrochemical C–N bond activation for deaminative reductive coupling of Katritzky salts

Yeqing Liu; Xiangzhang Tao; Yu Mao; Xin Yuan; Jiangkai Qiu; Linyu Kong; Shengyang Ni; Kai Guo; Yi Wang; Yi Pan

doi:10.1038/s41467-021-27060-7

Electrochemical C–N bond activation for deaminative reductive coupling of Katritzky salts

Yeqing Liu, Xiangzhang Tao, Yu Mao, Xin Yuan, Jiangkai Qiu, Linyu Kong, Shengyang Ni, Kai Guo, Yi Wang, Yi Pan

COLLEGE OF BIOTECHNOLOGY AND PHARMACEUTICAL ENGINEERING

Research output: Contribution to journal › Article › peer-review

55 Scopus citations

Abstract

Electrosynthesis has received great attention among researchers in both academia and industry as an ideal technique to promote single electron reduction without the use of expensive catalysts. In this work, we report the electrochemical reduction of Katritzky salts to alkyl radicals by sacrificing the easily accessible metal anode. This catalyst and electrolyte free platform has broad applicability to single electron transfer chemistry, including fluoroalkenylation, alkynylation and thiolation. The deaminative functionalization is facilitated by the rapid molecular diffusion across microfluidic channels, demonstrating the practicality that outpaces the conventional electrochemistry setups.

Original language	English
Article number	6745
Journal	Nature Communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-021-27060-7
State	Published - Dec 2021

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abstract = "Electrosynthesis has received great attention among researchers in both academia and industry as an ideal technique to promote single electron reduction without the use of expensive catalysts. In this work, we report the electrochemical reduction of Katritzky salts to alkyl radicals by sacrificing the easily accessible metal anode. This catalyst and electrolyte free platform has broad applicability to single electron transfer chemistry, including fluoroalkenylation, alkynylation and thiolation. The deaminative functionalization is facilitated by the rapid molecular diffusion across microfluidic channels, demonstrating the practicality that outpaces the conventional electrochemistry setups.",

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AU - Liu, Yeqing

AU - Tao, Xiangzhang

AU - Mao, Yu

AU - Yuan, Xin

AU - Qiu, Jiangkai

AU - Kong, Linyu

AU - Ni, Shengyang

AU - Guo, Kai

AU - Wang, Yi

AU - Pan, Yi

PY - 2021/12

Y1 - 2021/12

N2 - Electrosynthesis has received great attention among researchers in both academia and industry as an ideal technique to promote single electron reduction without the use of expensive catalysts. In this work, we report the electrochemical reduction of Katritzky salts to alkyl radicals by sacrificing the easily accessible metal anode. This catalyst and electrolyte free platform has broad applicability to single electron transfer chemistry, including fluoroalkenylation, alkynylation and thiolation. The deaminative functionalization is facilitated by the rapid molecular diffusion across microfluidic channels, demonstrating the practicality that outpaces the conventional electrochemistry setups.

AB - Electrosynthesis has received great attention among researchers in both academia and industry as an ideal technique to promote single electron reduction without the use of expensive catalysts. In this work, we report the electrochemical reduction of Katritzky salts to alkyl radicals by sacrificing the easily accessible metal anode. This catalyst and electrolyte free platform has broad applicability to single electron transfer chemistry, including fluoroalkenylation, alkynylation and thiolation. The deaminative functionalization is facilitated by the rapid molecular diffusion across microfluidic channels, demonstrating the practicality that outpaces the conventional electrochemistry setups.

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Electrochemical C–N bond activation for deaminative reductive coupling of Katritzky salts

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