电合成
乙胺
材料科学
法拉第效率
催化作用
吸附
乙腈
电解
化学工程
无机化学
电化学
选择性
制氢
氢
亚胺
电催化剂
电解水
反应中间体
纳米棒
多相催化
选择性吸附
纳米技术
质子交换膜燃料电池
作者
Han Du,Xuan Wang,Meng Li,Ransheng Lv,C Y Wang,Wentao Xue,Lei Ren,Dongmei Sun,Yawen Tang,H. C. Li,Gengtao Fu
标识
DOI:10.1002/adma.202521105
摘要
Electrocatalytic hydrogenation of acetonitrile (AN-ECH) offers a sustainable pathway for ethylamine (EA) synthesis. However, achieving high selectivity in AN-ECH necessitates carefully balancing proton availability to suppress the hydrogen evolution reaction (HER), which often conflicts with the proton supply requirements under industrial-grade current densities. Herein, we design and develop a novel and effective AN-ECH catalyst consisting of rare-earth Eu atoms modified on Cu2O nanoneedles to drive efficient and durable AN-ECH at ampere-level currents. The optimized Eu-Cu2O catalyst achieves a high EA Faradaic efficiency of 98.1 % and an exceptional production rate of 2253.2 µmol h-1 cm-2 compared with pure Cu2O. Notably, the Eu-Cu2O can continuously operate 420 h at 2 A in an anion-exchange membrane electrolyzer for AN-ECH, representing the longest reported stability under the industrial-current conditions to date. Operando characterization and theoretical calculations elucidate that the Eu incorporation tailors the electronic structure of Cu sites, thus switching the adsorption configuration of AN from the flat-lying multi-site π-adsorption to vertical N-end adsorption. This reconfiguration of the adsorption site lowers the energy barrier for the imine hydrogenation step, dictating the ideal proton addition pathway while enhancing the proton addition kinetics to suppress the HER. This work provides fundamental insights into rare-earth tuning of AN hydrogenation mechanisms and represents a critical advancement toward ampere-scale electrosynthesis of EA.
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