析氧
过电位
化学物理
氧气
镧系元素
化学
材料科学
联轴节(管道)
格子(音乐)
密度泛函理论
能量转换
反应机理
机制(生物学)
光化学
物理化学
催化作用
工作(物理)
电子能带结构
化学工程
氧化还原
纳米技术
活化能
作者
Baoxin Ge,Pengyang Jiang,Caijin Huang,Biyi Chen,Xiaoqing Qiu
标识
DOI:10.1021/acssuschemeng.5c10142
摘要
The effective activation of lattice oxygen can be triggered by modulating the metal–O covalency to activate the lattice oxygen oxidation mechanism (LOM) for the OER. In this work, we perform a systematic and comprehensive DFT screening across the entire lanthanide series to modulate the Ni–O covalency by constructing Ln–O–Ni orbital gradient coupling. We found that the Ni–O covalency can be maximized by the Gd(4f)–O(2p)–Ni(3d) gradient orbital coupling structure formed by Gd doping. Moreover, this structure effectively activates lattice oxygen for reaction participation by elevating the Ni 3d/O 2p band centers and promoting the formation of oxygen vacancies. Therefore, the OER mechanism changes from the adsorbate evolution mechanism to LOM, accelerating the generation of *OO intermediates, which, in turn, significantly lowers the reaction energy barrier. The as-prepared 2% Gd–NiO sample exhibited remarkable stability (180 h) and a low OER overpotential (235 mV@10 mA cm–2), outperforming most of the reported Ni-based alkaline OER electrocatalysts. Moreover, the Zn–air battery constructed with 2% Gd–NiO achieved an excellent energy conversion efficiency and cycling stability. This work provides a theoretical framework for the design of advanced LOM catalysts.
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