超分子化学
化学
碱金属
分子
光谱学
无机化学
工作(物理)
合理设计
材料科学
离子
催化作用
化学工程
纳米技术
组合化学
水溶液
金属
小分子
作者
Tianyang Liu,Youchao Yang,Zhiheng Ma,An Chen,Xianlong Zhou,Yu Jing
摘要
ABSTRACT Performance deterioration in the electrocatalytic hydrogenation (ECH) of concentrated biomass platform molecules remains a major obstacle for practical implementation, largely due to an incomplete understanding of concentration‐dependent mechanisms. Using the 5‐hydroxymethylfurfural reduction reaction (HMFRR) as a model system, we uncover an unanticipated role of intermolecular hydrogen bonding under high reactant concentrations as revealed by constant‐potential DFT calculations and AIMD simulations. Guided by this mechanistic insight, we develop a cation‐modulation strategy and identify Li + ion as the most effective promoter of HMFRR, via a synergistic combination of (i) disruption of intermolecular hydrogen bonds in HMF dimers enabled by the small ionic radius, deep penetration into the inner Helmholtz plane and low coordinated structure of Li + , (ii) enhanced *H transfer arising from its strong electron‐withdrawing character, and (iii) preservation of high HMFRR selectivity at moderate Li + concentrations. Experimental electrochemical measurements and 1 H nuclear magnetic resonance ( 1 H NMR) spectroscopy validate these predictions. This work resolves a long‐standing challenge in high‐concentration ECH and establishes a generalizable paradigm for upgrading concentrated biomass‐derived platform molecules through rational interfacial engineering.
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