Highly enhanced electrocatalytic OER with facile electrodeposition of MIL–53(Fe)/NiAl–LDH/NF and NiAl–LDH/MIL–53(Fe)/NF

[Display omitted] •A novel composited structure using MIL-53(Fe) and NiAl-LDH through the LBL deposition method.•Superior OER activity of MIL-53(Fe)/NiAl-LDH/NF compared to the reversed configuration.•A larger surface area in the optimal composite leading to higher OER efficiency.•Excellent long-ter...

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Bibliographic Details
Published in:Electrochemistry communications 2024-11, Vol.168, p.107825, Article 107825
Main Authors: Ahmadi, Afsaneh, Chahkandi, Mohammad, Zargazi, Mahboobeh, Chung, Jin Suk
Format: Article
Language:English
Subjects:
Electrophoretic deposition
Layer-by-layer
MIL-53(Fe)/NiAl-LDH/NF
NiAl-LDH/MIL-53(Fe)/NF
Oxygen evolution reaction
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Summary:[Display omitted] •A novel composited structure using MIL-53(Fe) and NiAl-LDH through the LBL deposition method.•Superior OER activity of MIL-53(Fe)/NiAl-LDH/NF compared to the reversed configuration.•A larger surface area in the optimal composite leading to higher OER efficiency.•Excellent long-term stability of the MIL-53(Fe)/NiAl-LDH/NF composite.•The study highlights the importance of layer arrangement in composite design for maximizing performance. This research investigates a new approach to improve the electrocatalytic rate of the Oxygen Evolution Reaction (OER), a key step in water electrolysis. The study focuses on two promising materials: MIL–53(Fe) and NiAl–LDH. MIL–53(Fe) offers several advantages: high catalytic activity, large surface area, and good chemical stability. NiAl–LDH is attractive due to its layered structure, tolerance to a wide range of pH levels, scalability, and cost-effectiveness. However, their limitations like low conductivity and restricted accessibility of active sites hinder their performance in water splitting applications. To address these limitations, novel composite thin films were created using a technique called layer–by–layer (LBL) electrophoretic deposition. These films, built on nickel foam (NF) substrates, included two configurations: MIL–53(Fe)/NiAl–LDH/NF and NiAl–LDH/MIL–53(Fe)/NF. The MIL-53(Fe)/NiAl-LDH/NF composite exhibited remarkable OER activity in alkaline electrolytes, requiring overpotentials of only 200, 270, and 370 mV to reach current densities of 20, 50, and 100 mA cm−2, respectively. The Tafel slope of 54.86 mVdec−1 suggests rapid reaction kinetics. Additionally, it demonstrated excellent long-term stability, lasting for at least 20 h. The success of the MIL–53(Fe)/NiAl–LDH/NF composite can be attributed to the LBL technique. This method creates a composite with a larger surface area, significantly improving OER efficiency. In contrast, the MIL–53(Fe)/NiAl–LDH/NF configuration had the opposite effect. The NF pores became blocked by the MIL–53(Fe) layer, reducing the overall surface area, hindering electron transfer, and thereby limiting oxygen production. The LBL deposition method used in this study proves its effectiveness in designing efficient electrocatalysts. This opens up possibilities for creating other multicomponent materials for energy applications. The findings provide valuable insights for future research on these promising composite materials, potentially leading to the development
ISSN:1388-2481
DOI:10.1016/j.elecom.2024.107825