控制合成MOF衍生的中空和黄壳纳米笼,用于改善水氧化和选择性乙二醇重整

IF 42.9 Q1 ELECTROCHEMISTRY
Minghong Huang , Changsheng Cao , Li Liu , Wenbo Wei , Qi-Long Zhu , Zhenguo Huang
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引用次数: 5

摘要

精心设计的金属-有机框架(MOF)衍生的纳米结构电催化剂对于改善析氧反应的反应动力学和调节小有机分子氧化反应的选择性至关重要。在此,新型草酸盐改性的空心CoFe基层状双氢氧化物纳米笼(h-CoFe-LDH NCs)和卵黄壳ZIF@CoFe-LDH纳米笼(ys-ZIF@CoFe-LDHNCs)是通过钴基MOF前体(ZIF-67)的蚀刻-掺杂重建策略开发的。独特的纳米结构,以及第二金属元素和嵌入的草酸盐基团的结合,使h-CoFe-LDH NCs和ys-ZIF@CoFe-LDHNCs暴露出更多具有高内在活性的活性位点。所得的h-CoFe-LDH NCs表现出优异的OER活性,过电位仅为278​mV以提供50的电流密度​毫安​cm−2。此外,控制重建程度可以形成ys-ZIF@CoFe-LDH具有蛋黄壳纳米笼纳米结构的NCs,对乙二醇对甲酸盐的选择性氧化反应(EGOR)表现出出色的电催化性能,法拉第效率高达91%。因此,使用Pt/C将EGOR和析氢反应集成在一起的混合水电解系统||ys-ZIF@CoFe-LDHNCs被探索用于节能制氢,需要电池电压127​比水电解低mV以实现50的电流密度​毫安​cm−2。这项工作证明了设计先进的MOF衍生电催化剂以增强电催化反应的可行方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Controlled synthesis of MOF-derived hollow and yolk–shell nanocages for improved water oxidation and selective ethylene glycol reformation

Controlled synthesis of MOF-derived hollow and yolk–shell nanocages for improved water oxidation and selective ethylene glycol reformation

Delicately designed metal–organic framework (MOF)-derived nanostructured electrocatalysts are essential for improving the reaction kinetics of the oxygen evolution reaction and tuning the selectivity of small organic molecule oxidation reactions. Herein, novel oxalate-modified hollow CoFe-based layered double hydroxide nanocages (h-CoFe-LDH NCs) and yolk–shell ZIF@CoFe-LDH nanocages (ys-ZIF@CoFe-LDH NCs) are developed through an etching–doping reconstruction strategy from a Co-based MOF precursor (ZIF-67). The distinctive nanostructures, along with the incorporation of the secondary metal element and intercalated oxalate groups, enable h-CoFe-LDH NCs and ys-ZIF@CoFe-LDH NCs to expose more active sites with high intrinsic activity. The resultant h-CoFe-LDH NCs exhibit outstanding OER activity with an overpotential of only 278 ​mV to deliver a current density of 50 ​mA ​cm−2. Additionally, controlling the reconstruction degree enables the formation of ys-ZIF@CoFe-LDH NCs with a yolk–shell nanocage nanostructure, which show outstanding electrocatalytic performance for the selective ethylene glycol oxidation reaction (EGOR) toward formate, with a Faradaic efficiency of up to 91%. Consequently, a hybrid water electrolysis system integrating the EGOR and the hydrogen evolution reaction using Pt/C||ys-ZIF@CoFe-LDH NCs is explored for energy-saving hydrogen production, requiring a cell voltage 127 ​mV lower than water electrolysis to achieve a current density of 50 ​mA ​cm−2. This work demonstrates a feasible way to design advanced MOF-derived electrocatalysts toward enhanced electrocatalytic reactions.

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