选择性
催化作用
法拉第效率
铜
电解
氮化物
化学工程
生物量(生态学)
化学
吸附
无机化学
氮气
协同催化
材料科学
水解
电解水
电催化剂
氧化还原
酰胺
多相催化
纳米笼
羟甲基糠醛
作者
Ju Huang,Jianqiu Zhu,Bowen Liu,Chencheng Dai,Zhimin Chen,Hao Wu,Gang Li,Shichao Du,Yi-Xiang Wang,Zhiyu Ren,Zhichuan J. Xu,Honggang Fu
标识
DOI:10.1038/s41467-026-72690-4
摘要
Achieving high selectivity in the electrocatalytic hydrogenation (ECH) of concentrated 5-hydroxymethylfurfural (HMF) to 2,5-dihydroxymethylfuran (DHMF) remains a challenge due to competitive adsorption at high HMF concentrations, which limits active-site availability and suppresses *H generation. Regulating the balance between *H generation and HMF adsorption is therefore essential for maintaining selectivity under practical conditions. Here we show a surface amide-functionalized copper nitride catalyst (Ami-Cu3N) featuring dual-nitrogen active sites. The catalyst achieves >99% DHMF selectivity and >98% Faradaic efficiency, with a production rate of 63.4 mmol cm-2 h-1 at 500 mA cm-2 under concentrated HMF conditions. Mechanistic studies indicate that the combined roles of lattice nitrogen (promoting water dissociation) and amide nitrogen (modulating HMF adsorption) lower the energy barriers for both *H formation and HMF hydrogenation, facilitating high activity and selectivity. In addition, a coupled electrolysis system enables simultaneous production of value-added products at both electrodes. These findings provide design principles for electrocatalysts that enable selective biomass conversion at high reaction rates. Biomass electro-hydrogenation offers a sustainable route to value-added chemicals but suffers poor selectivity at high current densities. Here, the authors report an amide-functionalized Cu3N catalyst enabling near-quantitative HMF-to-DHMF conversion under industrially relevant conditions.
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