Citation: Junsong Zhong, Yi Yu, Dongliang Zhang, Keyin Ye. Merging cobalt catalysis and electrochemistry in organic synthesis^☆[J]. Chinese Chemical Letters, ;2021, 32(3): 963-972. doi: 10.1016/j.cclet.2020.08.011 shu

Merging cobalt catalysis and electrochemistry in organic synthesis^☆

Key Laboratory of Molecule Synthesis and Function Discovery (Fujian Province University), College of Chemistry, Fuzhou University, Fuzhou 350108, China

Author Bio: Junsong Zhong obtained his BSc degree in chemical biology from Xiamen University in 2019. Then he continued his research at Fuzhou University under the guidance of Prof. Ke-Yin Ye. His research interests focuse on electrochemical synthesis
Yi Yu obtained her master degree in organic chemistry in 2019 from Jiangxi Normal University. Then she moved to the Fuzhou University for her doctoral studies under the guidance of Prof. Ke-Yin Ye. Her research interests focuse on electrochemical synthesis
Dongliang Zhang is an undergraduate student at Fuzhou University. At present, he is studying and working in Prof. Ke-Yin Ye's research group. His research focuses on electrochemical synthesis
Prof. Dr. Keyin Ye obtained his bachelor degree from Xiamen University (mentors: Prof. Pei-Qiang Huang and Prof. Hong-Kui Zhang) and PhD from Shanghai Institute of Organic Chemistry (mentors: Prof. Li-Xin Dai and Prof. Shu-Li You). He then conducted his postdoctoral research with Prof. Gerhard Erker (Universität Münster) and Prof. Song Lin (Cornell University), respectively. Since June 2019 he started his independent career at Fuzhou University as a Minjiang Professor. His research interests include organometallics, asymmetric catalysis and electrosynthesis

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kyye@fzu.edu.cn

Received Date: 28 June 2020
Revised Date: 24 July 2020
Accepted Date: 10 August 2020
Available Online: 12 August 2020

Figures(23)

There is an increasing demand of using the low-cost and sustainable cobalt to replace its noble congeners (rhodium and iridium) as reflected by the recent upsurge of cobalt catalysis in the diverse organic transformations. Since all the redox reactivity of cobalt catalysis highly relies on the capability of the interconversion between their oxidation states (most frequently +1, +2 and +3), electrochemistry perfectly meets such a requirement owing to its outstanding performance in the redox manipulation. In this review, we highlight the recent advances in the merger of cobalt catalysis and electrochemistry in organic synthesis.
- Cobalt,
- Catalysis,
- Electrochemistry,
- Organic synthesis,
- Sustainable chemistry
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Merging cobalt catalysis and electrochemistry in organic synthesis☆

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Merging cobalt catalysis and electrochemistry in organic synthesis^☆