The future of organic electrochemistry current transfer

The electrostatic attraction between electrons and nuclei is a fundamental force in electrochemistry. This force drives the interaction between electrons and nuclei, providing the potential for redox reactions. As a result, it is the basis of redox chemistry. In recent years, organic electrochemistry has made significant progress in oxidative hydrogen evolution coupling and sacrificial anode electrore-duction, thanks to its efficient and environmentally friendly capacity to create reactive intermedi-ates. This paper focuses on several areas in the field of electrochemistry, including optimizing elec-trode materials, developing new electrolytic catalysts, paired electrolysis, photoelectrocatalysis, bioelectrosynthesis, and artificial intelligence-assisted electrosynthesis. The aim is to optimize reac-tion mechanisms and explore interdisciplinary combinations. (c) 2023, Dalian Institute of Chemical Physics, Chinese Academy of Sciences. Published by Elsevier B.V. All rights reserved.

Automated summary

The electrostatic attraction between electrons and nuclei is a fundamental force in electrochemistry, driving the interaction between them and enabling redox reactions. Recent advancements in organic electrochemistry have focused on optimizing electrode materials, developing new catalysts, and exploring interdisciplinary combinations to enhance reaction mechanisms. These developments have contributed to the efficient and environmentally friendly creation of reactive intermediates.