表面改性高岭土纳米管协同增强析氧催化作用

IF 2.2 4区工程技术 Q3 ELECTROCHEMISTRY

Journal of electrochemical science and technology Pub Date : 2023-02-28 DOI:10.33961/jecst.2022.00906

Hyeongwon Jeong, B. Sharma, Jae‐ha Myung

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引用次数: 0

摘要

采用表面改性的高岭土纳米管(Fe3O4-HNTs)结构，引入了协同提高氧化锰(MnO2)催化剂的析氧反应(OER)。通过一系列湿化学和水热法将片状二氧化锰催化剂附着在纳米管模板(Fe3O4-HNTs)上。MnO2和Fe3O4-HNTs之间的强相互作用使OER的电荷转移反应的活性表面积和连通性最大化。Fe3O4层与MnO2催化剂之间的协同作用使Mn离子部分被Fe离子取代，从而提高了Mn3+/Mn4+的比例。相对增加的MnO2@FHNTs上的Mn3+/Mn4+比值诱导σ*轨道(eg)占据接近单电子，提高了OER性能。与未修饰的MnO2 (0.65 V, 219 mV/dec)和原始MnO2 (0.53 V, 205 mV/dec)相比，MnO2@FHNTs催化剂在10 mA/cm2下的过电位(E vs RHE)降低了0.42 V, Tafel斜率(99 mV/dec)。本研究为制备纳米纤维化OER催化剂提供了一种简单、创新的方法，在能量转换和存储系统中具有广泛的应用前景。

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Synergistically Enhanced Oxygen Evolution Catalysis with Surface Modified Halloysite Nanotube

Synergistically increased oxygen evolution reaction (OER) of manganese oxide (MnO₂) catalyst is introduced with surface-modified halloysite nanotube (Fe₃O₄-HNTs) structure. The flake shaped MnO₂ catalyst is attached on the nanotube template (Fe₃O₄-HNTs) by series of wet chemical and hydrothermal method. The strong interaction between MnO₂ and Fe₃O₄-HNTs maximized active surface area and inter-connectivity for festinate charge transfer reaction for OER. The synergistical effect between Fe₃O₄ layer and MnO₂ catalyst enhance the Mn³⁺/Mn⁴⁺ ratio by partial replacement of Mn ions with Fe. The relatively increased Mn^3+/Mn⁴⁺ ratio on MnO₂@FHNTs induced σ^* orbital (e_g) occupation close to single electron, improving the OER performances. The MnO₂@FHNTs catalyst exhibited the reduced overpotential of 0.42 V (E vs. RHE) at 10 mA/cm² and Tafel slope of (99 mV/dec), compared with that of MnO₂ with unmodified HNTs (0.65 V, 219 mV/dec) and pristine MnO₂ (0.53 V, 205 mV/dec). The present study provides simple and innovative method to fabricate nano fiberized OER catalyst for a broad application of energy conversion and storage systems.

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来源期刊

Journal of electrochemical science and technology ELECTROCHEMISTRY-

CiteScore

6.30

自引率

8.10%

发文量

期刊介绍： Covering fields: - Batteries and Energy Storage - Biological Electrochemistry - Corrosion Science and Technology - Electroanalytical Chemistry and Sensor Technology - Electrocatalysis - Electrochemical Capacitors & Supercapcitors - Electrochemical Engineering - Electrodeposition and Surface Treatment - Environmental Science and Technology - Fuel Cells - Material Electrochemistry - Molecular Electrochemistry and Organic Electrochemistry - Physical Electrochemistry - Solar Energy Conversion and Photoelectrochemistry