材料科学
氢
电化学
氨
离解(化学)
硝酸盐
无机化学
氨生产
密度泛函理论
化学工程
法拉第效率
电合成
分解水
氧化物
硝酸锌
化学物理
硫化氢
交换电流密度
分析化学(期刊)
产量(工程)
反硝化
氢溢流
氢气储存
动能
硫化物
作者
Fengting Xie,Xuxin Kang,Zongtai Li,Honglin Zhu,Lei Wang,Ziyang Wu,Jianping Yang
摘要
ABSTRACT Electrochemical nitrate reduction (NO 3 RR) under ambient conditions offers a sustainable route for ammonia (NH 3 ) synthesis; however, its efficiency is restricted by the kinetic mismatch between water dissociation and nitrate hydrogenation. Here, we design Ag/CoNiS heterostructures in which Ag loading density programs interfacial confinement to regulate hydrogen spillover from CoNiS water‐activation domains to Ag‐associated nitrate/nitrogen oxide (NO x ) intermediates, thereby coupling * H generation, relay, and deep nitrate hydrogenation. The optimized Ag M /CoNiS achieves an NH 3 yield of 22.31 mg h −1 cm −2 with 99.13% Faradaic efficiency. In situ Raman, distribution of relaxation times (DRT) analysis, hydrogen/deuterium (H/D) isotope experiments, and tert‐butanol (TBA) perturbation tests reveal that the confined Ag–CoNiS interface regulates interfacial water and establishes a balanced * H supply–consumption regime, thereby suppressing competing hydrogen evolution. Density functional theory (DFT) calculations further show that Ag facilitates nitrate deoxygenation, whereas excessive Ag coverage weakens Co/Ni‐centered water activation, explaining the volcano‐type activity trend. Coupling NO 3 RR with the sulfide oxidation reaction (SOR) further enables a low‐voltage NO 3 RR||SOR electrolyzer, requiring only 0.70 V at 50 mA cm −2 for energy‐saving co‐production of ammonia and sulfur.
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