电合成
环己酮
羟胺
材料科学
无机化学
合金
电解
法拉第效率
电化学
化学工程
催化作用
环己酮肟
产量(工程)
吸附
化学
微型反应器
歧化过程
多相催化
化学吸附
有机化学
组合化学
偶联反应
胺化
分解水
作者
Panlong Zhai,Chen Wang,Guan Sheng,C. Ye,Jungang Hou,Qinfen Gu,Tao Ling,Ye Zhu,Pei Liang,Xin Wang,Jieqiong Shan
摘要
ABSTRACT The electrosynthesis of cyclohexanone oxime from cyclohexanone and nitrogenous feedstock driven by renewable electricity presents a sustainable alternative to energy‐intensive and hazardous industrial processes. However, achieving high activity and selectivity is challenged by the over‐reduction of key intermediates and the lack of effective sites for C─N coupling. Herein, we report a Fe 1 Bi single‐atom alloy (Fe 1 Bi SAA) featuring Fe‐Bi atomic interfaces that collaborate for the one‐pot electrosynthesis of cyclohexanone oxime. The Fe 1 Bi SAA achieves a remarkable Faradaic efficiency of 70.9% and a yield rate of 0.94 mmol cm −2 h −1 for cyclohexanone oxime. Combined in situ electrochemical spectroscopic measurements and density functional theory calculations reveal an atomic‐scale synergistic mechanism: dispersed Fe sites adsorb and activate cyclohexanone, while adjacent Bi sites selectively reduce nitrite to the key hydroxylamine intermediate. The techno‐economic analysis based on flow electrolyzer operation confirms the potential economic viability of the electrosynthesis of cyclohexanone oxime. This work provides profound atomic‐level insight into cooperative catalysis for C─N coupling reactions toward the electrosynthesis of value‐added organonitrogen compounds.
科研通智能强力驱动
Strongly Powered by AbleSci AI