Universal high-efficiency electrocatalytic olefin epoxidation via a surface-confined radical promotion

Ran, Pan; Qiu, Aoqian; Liu, Tianshu; Wang, Fangyuan; Tian, Bailin; Xiang, Beiyao; Li, Jun; Lv, Yang; Ding, Mengning

Universal high-efficiency electrocatalytic olefin epoxidation via a surface-confined radical promotion

Pan Ran, Aoqian Qiu, Tianshu Liu, Fangyuan Wang, Bailin Tian, Beiyao Xiang, Jun Li, Yang Lv and Mengning Ding ()
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Pan Ran: Nanjing University
Aoqian Qiu: Nanjing University
Tianshu Liu: Nanjing University
Fangyuan Wang: Nanjing University
Bailin Tian: Nanjing University
Beiyao Xiang: Nanjing University
Jun Li: Nanjing University
Yang Lv: Nanjing University
Mengning Ding: Nanjing University

Nature Communications, 2024, vol. 15, issue 1, 1-12

Abstract: Abstract Production of epoxides via selective oxidation of olefins affords a fundamental source of key intermediates for the industrial manufacture of diverse chemical stocks and materials. Current oxidation strategy generally works under harsh conditions including high temperature, high pressure, and/or request for potentially hazardous oxidants, leading to substantial challenges in sustainability and energy efficiency. To this end, direct electrocatalytic epoxidation poses as a promising solution to these issues, yet their industrial applications are limited by the low selectivity, low yield, and poor stability of the electrocatalysts. Here we report a universal electrochemical epoxidation approach via a kinetically confined surface radical pathway. High epoxidation efficiency can be achieved under mild working conditions (e.g., >99% selectivity, >80% yield and >80% Faraday efficiency for cyclohexene-to-cyclohexene oxide conversion), which can be extended to broad scope of olefin substrates. The catalytic performance originated from a surface bimolecular (L-H) reaction mechanism involving formation and surface confinement of bromine radicals due to kinetic restriction, which effectively activates inert C=C bonds while avoiding the homogenous radical side reactions. With the use of renewable energy and water as green oxygen source, successful implementation of this approach will pave the way for more sustainable chemical production and manufacturing.

Date: 2024
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DOI: 10.1038/s41467-024-53049-z

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