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首页> 外文期刊>Journal of Materials Chemistry, A. Materials for energy and sustainability >Selective phosphidation: an effective strategy toward CoP/CeO2 interface engineering for superior alkaline hydrogen evolution electrocatalysis
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Selective phosphidation: an effective strategy toward CoP/CeO2 interface engineering for superior alkaline hydrogen evolution electrocatalysis

机译:选择性磷酸化:用于COP / CEO2界面工程的有效策略,用于高级碱性氢气进化电催化

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摘要

Co phosphides, although highly active for the hydrogen evolution electrocatalysis in acids, still deliver inferior performance in alkalis, limiting their application in alkaline water electrolysis. Building an effective Co phosphide/(hydroxide) oxide interface could be a viable way to improve the hydrogen evolution activity of Co phosphide catalysts under alkaline conditions, which however remains unexplored and challenging. In this communication, we report the facile development of a CoP-CeO2 hybrid nanosheet film on Ti mesh (CoP-CeO2/Ti) from easily made Co3O4-CeO2 via a selective phosphidation strategy. In 1.0 M KOH, such CoP-CeO2/Ti achieves a geometrical catalytic current density of 10 mA cm(-2) at a pretty low overpotential of 43 mV, 27 mV less than that for CoP/Ti. Remarkably, our CoP-CeO2/Ti also shows superior durability over CoP/Ti, suggesting that CeO2 greatly stabilizes the CoP catalyst. Density functional theory calculations demonstrate that CoP-CeO2 possesses a lower water dissociation free energy and a more optimal hydrogen adsorption free energy than CoP. This selective phosphidation strategy is universal in engineering the transition metal phosphide/oxide interface for applications.
机译:磷化磷酸,但酸中氢进化电催化高度活跃,仍然可以在碱中提供较差的性能,限制了它们在碱性水电解中的应用。建立有效的CO磷化物/(氢氧化物)氧化物界面可以是改善碱性条件下CO磷化物催化剂的氢进化活性的可行方法,然而仍然是未开发和挑战性的。在这一沟通中,我们通过选择性磷化策略从易于制造CO3O4-CEO2的TI网格(COP-CEO2 / TI)上报告了COP-CEO2混合纳米片薄膜的容易开发。在1.0 m KOH中,这种COP-CEO2 / TI在43mV的相当低的过电位下实现10 mA cm(-2)的几何催化电流密度,比COP / TI小于23mV,27mV。值得注意的是,我们的COP-CEO2 / TI也显示出对COP / TI的卓越耐用性,表明CEO2大大稳定了COP催化剂。密度函数理论计算表明,COP-CEO2具有较低的水解离能量和比COP更优于最佳的氢吸收自由能。这种选择性磷化术策略在工程过渡金属磷化物/氧化物界面进行了通用。

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  • 作者

    Zhang Rong; Ren Xiang; Hao Shuai; Ge Ruixiang; Liu Zhiang; Asiri Abdullah M.; Chen Liang; Zhang Qiuju; Sun Xuping;

  • 作者单位

    Sichuan Univ Coll Chem Chengdu 610064 Sichuan Peoples R China;

    Sichuan Univ Coll Chem Chengdu 610064 Sichuan Peoples R China;

    Sichuan Univ Coll Chem Chengdu 610064 Sichuan Peoples R China;

    Chinese Acad Sci Ningbo Inst Mat Technol &

    Engn Ningbo 315201 Zhejiang Peoples R China;

    Qufu Normal Univ Coll Chem &

    Chem Engn Qufu 273165 Shandong Peoples R China;

    King Abdulaziz Univ Chem Dept Fac Sci Jeddah 21589 Saudi Arabia;

    Chinese Acad Sci Ningbo Inst Mat Technol &

    Engn Ningbo 315201 Zhejiang Peoples R China;

    Chinese Acad Sci Ningbo Inst Mat Technol &

    Engn Ningbo 315201 Zhejiang Peoples R China;

    Sichuan Univ Coll Chem Chengdu 610064 Sichuan Peoples R China;

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  • 正文语种 eng
  • 中图分类 工程材料学;
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