Electron Manipulation and Surface Reconstruction of Bimetallic Iron-Nickel Phosphide Nanotubes for Enhanced Alkaline Water Electrolysis.
Xinqiang WangJinhao ZhouWengang CuiFan GaoYong GaoFulai QiYanxia LiuXiaoying YangKe WangZhenglong LiYaxiong YangJian ChenWenping SunLixian SunHongge PanPublished in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2024)
Developing high-efficiency and stable bifunctional electrocatalysts for water splitting remains a great challenge. Herein, NiMoO 4 nanowires as sacrificial templates to synthesize Mo-doped NiFe Prussian blue analogs are employed, which can be easily phosphorized to Mo-doped Fe 2x Ni 2(1-x) P nanotubes (Mo-FeNiP NTs). This synthesis method enables the controlled etching of NiMoO 4 nanowires that results in a unique hollow nanotube architecture. As a bifunctional catalyst, the Mo-FeNiP NTs present lower overpotential and Tafel slope of 151.3 (232.6) mV at 100 mA cm -2 and 76.2 (64.7) mV dec -1 for HER (OER), respectively. Additionally, it only requires an ultralow cell voltage of 1.47 V to achieve 10 mA cm -2 for overall water splitting and can steadily operate for 200 h at 100 mA cm -2 . First-principles calculations demonstrate that Mo doping can effectively adjust the electron redistribution of the Ni hollow sites to optimize the hydrogen adsorption-free energy for HER. Besides, in situ Raman characterization reveals the dissolving of doped Mo can promote a rapid surface reconstruction on Mo-FeNiP NTs to dynamically stable (Fe)Ni-oxyhydroxide layers, serving as the actual active species for OER. The work proposes a rational approach addressed by electron manipulation and surface reconstruction of bimetallic phosphides to regulate both the HER and OER activity.
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