氨生产
电化学
电合成
无机化学
析氧
吸附
材料科学
空位缺陷
氧气
吉布斯自由能
氨
密度泛函理论
亚硝酸盐
氮气
氧化物
光化学
电子转移
化学
电极
化学物理
氢
电化学能量转换
原位
化学工程
极化(电化学)
硝酸盐
氧化还原
钝化
可逆氢电极
溶解
分子
作者
Yifei Shan,Jingdong Li,Songyu Du,Zhiwen Cheng,Chenyu Bao,Yushan Chen,Jianxing Liang,Jinping Jia,Hongbo Zhang,Kan Li
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-04-16
标识
DOI:10.1021/acsnano.6c05674
摘要
Nitrate-to-ammonia electroreduction represents an environmentally friendly pathway for both ammonia synthesis and nitrogen source recovery. However, its efficiency is still limited by insufficient active sites to adsorb nitrate and activate H2O simultaneously. Herein, a kernel structure rearrangement strategy is proposed to construct a rapid electron transfer channel inside an urchin-like Cu-Co oxide using Pluronic@F127 as a template, which is beneficial for increasing the surface oxygen vacancy coverage after electrochemical in situ reconstruction. An ammonia production rate exceeding 0.25 mmol cm-2 h-1 and 100% Faraday efficiency (-0.2 V (RHE)) are achieved in neutral medium, superior to other reported three-dimensional materials. Density functional theory calculations and in situ characterizations reveal that the nitrate spatial hindrance caused by the increase of oxygen vacancy coverage makes it easier for the adjacent oxygen vacancy to adsorb H2O and produce active hydrogen. The rapid migration of active hydrogen between adjacent oxygen vacancies is beneficial for the reduction of the Gibbs free energy of *NO2 hydrogenation, minimizing the formation of the byproduct nitrite and thus promoting the energy utilization in both ammonia synthesis and Cl--mediated total nitrogen removal. The spatially hindered strategy proposed in this work provides a way to improve three-dimensional materials' electrochemical hydrogenation performances.
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