掺杂驱动的双异质界面结构提高了高电流密度下工业兼容型水分离的耐用性

IF 10.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Chunming Yang, Lihai Zhou, Zhijie Kong, Xiang Li, Wangchuan Zhu, Guangqing Wang, Yanzhong Zhen, Feng Fu, Yucang Liang
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引用次数: 0

摘要

在阴离子交换膜水电解槽(AEMWE)中开发工业兼容电流密度(>500 mA cm-2)的高稳定性电催化剂是水分离领域的一项巨大挑战。本文基于密度函数理论计算的结果,巧妙地设计了一种双异质界面结构的 NiSe/Fe-Ni(OH)2催化剂,并通过将掺杂铁的 Ni(OH)2电沉积在以 NiSe 为载体的泡沫镍(NF)上制备成功。在碱性条件下,NiSe/Fe-Ni(OH)2 中铁掺杂驱动的异质结构显著提高了工业兼容电流密度下单一氢气和氧气进化反应的催化活性和耐久性。特别是,NiSe/Fe-Ni(OH)2 在 600 mA cm-2 的条件下,至少 1000 小时的整体水分离性能损失可以忽略不计;在 600 mA cm-2 和 1 A cm-2 的条件下,作为 AEMWE 电极,在 85 °C 下至少 95 小时的长期耐用性也非常突出。由于掺杂铁引起了镍和铁之间强烈的协同效应,双重异质结构促进了电荷转移和再分布,催化活性位点丰富,稳定性和耐久性提高,因此提出了掺杂铁驱动异质界面结构促进催化性能的机制。这项研究提供了一个理论指导催化剂制备的成功范例,并为工业兼容的高电流密度水分离开创了一种创新战略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Doping-driven dual heterogeneous interfacial structures boosting the durability of industry-compatible water splitting at high current density

Developing highly stable electrocatalysts under industry-compatible current densities (>500 mA cm−2) in an anion-exchange membrane water electrolyzer (AEMWE) is an enormous challenge for water splitting. Herein, based on the results of density function theory calculations, a dual heterogeneous interfacial structured NiSe/Fe-Ni(OH)2 catalyst was subtly designed and successfully prepared by electrodepositing Fe-doped Ni(OH)2 on NiSe-loaded nickel foam (NF). Fe doping-driven heterogeneous structures in NiSe/Fe-Ni(OH)2 markedly boost catalytic activity and durability at industrially compatible current densities in single hydrogen and oxygen evolution reactions under alkaline conditions. In particular, NiSe/Fe-Ni(OH)2 shows a negligible performance loss at 600 mA cm−2 at least 1,000 h for overall water splitting, a distinguished long-term durability acting as AEMWE electrodes at 600 mA cm−2 and 1 A cm−2 at 85 °C for at least 95 h. Owing to Fe doping-induced strong synergetic effect between Ni and Fe, dual heterostructure-promoted charge transfer and redistribution, abundant catalytic active sites, and improvement of stability and durability, a mechanism of Fe doping-driven heterogeneous interfacial structure-promoted catalytic performance was proposed. This study provides a successful example of theory-directed catalyst preparation and pioneers a creative strategy for industry-compatible water splitting at high current density.

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来源期刊
Science China Chemistry
Science China Chemistry CHEMISTRY, MULTIDISCIPLINARY-
CiteScore
14.40
自引率
7.30%
发文量
3787
审稿时长
2.2 months
期刊介绍: Science China Chemistry, co-sponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China and published by Science China Press, publishes high-quality original research in both basic and applied chemistry. Indexed by Science Citation Index, it is a premier academic journal in the field. Categories of articles include: Highlights. Brief summaries and scholarly comments on recent research achievements in any field of chemistry. Perspectives. Concise reports on thelatest chemistry trends of interest to scientists worldwide, including discussions of research breakthroughs and interpretations of important science and funding policies. Reviews. In-depth summaries of representative results and achievements of the past 5–10 years in selected topics based on or closely related to the research expertise of the authors, providing a thorough assessment of the significance, current status, and future research directions of the field.
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