MOF-Derived FeCoO/N-Doped C Bifunctional Electrode for H2 Production Through Water and Glucose Electrolysis

IF 6.5 3区 材料科学 Q2 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Advanced Sustainable Systems Pub Date : 2024-09-02 DOI:10.1002/adsu.202400342
Meysam Tayebi, Zohreh Masoumi, Hyungwoo Lee, Daehyeon Hong, Bongkuk Seo, Choong-Sun Lim, Daeseung Kyung, Hyeon-Gook Kim
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Abstract

The glucose oxidation reaction (GOR) is a potential alternative to water oxidation because of its relatively low thermodynamic potential and the high availability of glucose. Herein, a FeCoO/N-doped C electrode derived from metal–organic framework (MOF) materials is applied, which is synthesized in several steps through the controlled deposition of Fe–Co oxide nanocatalysts onto Co –N-doped C nanofibers on a Ni foam substrate and demonstrate exceptional electrocatalytic activity for both the GOR and overall water splitting. Here, a bifunctional electrocatalyst derived from MOF, FeCoO/N-doped C is reported, for glucose oxidation reaction (GOR) and hydrogen evolution reaction (HER). The MOF-derived FeCoO/N-doped C (+/-) as a bifunctional electrocatalyst exhibits a cell voltage of 1.4 V for the GOR&HER, to reach a current density of 10 mA cm−2, which is 280 mV lower than that for the oxygen evolution reaction (OER)&HER (1.68 V). This study reveals that GOR is an energy-efficient and affordable source of H2 and value-added chemicals.

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通过水和葡萄糖电解产生 H2 的 MOF 衍生 FeCoO/N 掺杂 C 双功能电极
葡萄糖氧化反应(GOR)是水氧化反应的一种潜在替代方法,因为它的热力学潜力相对较低,而且葡萄糖的可用性很高。本文应用了一种源自金属有机框架(MOF)材料的 FeCoO/N 掺杂 C 电极,该电极是通过在镍泡沫基底上的 Co -N 掺杂 C 纳米纤维上可控沉积 Fe-Co 氧化物纳米催化剂,分几步合成的。本文报告了一种源自 MOF、FeCoO/N-掺杂 C 的双功能电催化剂,用于葡萄糖氧化反应(GOR)和氢进化反应(HER)。由 MOF 衍生的 FeCoO/N-掺杂 C (+/-) 作为双功能电催化剂,在葡萄糖氧化反应 &HER 中的电池电压为 1.4 V,电流密度为 10 mA cm-2,比氧进化反应 (OER)&HER 的电池电压(1.68 V)低 280 mV。这项研究表明,GOR 是一种高效节能且经济实惠的 H2 和增值化学品来源。
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来源期刊
Advanced Sustainable Systems
Advanced Sustainable Systems Environmental Science-General Environmental Science
CiteScore
10.80
自引率
4.20%
发文量
186
期刊介绍: Advanced Sustainable Systems, a part of the esteemed Advanced portfolio, serves as an interdisciplinary sustainability science journal. It focuses on impactful research in the advancement of sustainable, efficient, and less wasteful systems and technologies. Aligned with the UN's Sustainable Development Goals, the journal bridges knowledge gaps between fundamental research, implementation, and policy-making. Covering diverse topics such as climate change, food sustainability, environmental science, renewable energy, water, urban development, and socio-economic challenges, it contributes to the understanding and promotion of sustainable systems.
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