Modulation of a NiFe-Layered Double Hydroxide Electrode Using Zn Doping and Selective Etching Process for High-Performance Oxygen Evolution Reaction

Yeonsu Park; Suok Lee; Eunwoo Park; Yong-Hwan Mo; Juwon Lee; Jong Bae Park; Bong Kyun Kang; Younghyun Cho; Gyeong Hee Ryu; Sang-Beom Han; John Hong; Young-Woo Lee

doi:10.1002/bte2.70012

Battery Energy ›› 2025, Vol. 4 ›› Issue (4) :e70012 DOI: 10.1002/bte2.70012

RESEARCH ARTICLE

Modulation of a NiFe-Layered Double Hydroxide Electrode Using Zn Doping and Selective Etching Process for High-Performance Oxygen Evolution Reaction

Author information +

History +

PDF

Abstract

In the generation of green hydrogen and oxygen from water, transition metal-based electrode materials have been considered high-performance water-splitting catalysts. In water splitting, the oxygen evolution reaction (OER) is the rate-determining step. To overcome the high overpotential and slow kinetics of OER, the development of effective catalysts to improve electrolysis efficiency is essential. Nickel-iron-layered double hydroxides (NiFe-LDHs) have been recognized for their superior electrochemical performance under alkaline OER conditions and have emerged as promising catalysts owing to their unique structure that enhances electrolyte infiltration and exposes more active sites. However, the unique modulation of the crystalline structure of NiFe-LDHs can further improve OER performance. Accordingly, this study introduces an innovative synthesis approach based on Zn doping and selective Zn etching to increase the ECSA and induce favorable transition-metal oxidation states in NiFe-LDHs, thereby improving OER efficiency. After 6 h of Zn etching (Ni_2.9Zn_0.1Fe-6h), the optimized Ni_2.9Zn_0.1Fe LDH sample demonstrated remarkable electrochemical performance and stability, requiring small overpotentials of 192 and 260 mV at current densities of 10 and 100 mA cm^-2, respectively. Moreover, the Ni_2.9Zn_0.1Fe-6h electrode could maintain its original overpotential (260 mV) at a current density of 100 mA cm^-2 for 250 h. The proposed Zn doping and subsequent partial Zn etching can practically be applied to numerous high-performance transition metal-based electrochemical catalysts.

Keywords

cation vacancy / nickel-iron-layered double hydroxide / oxygen evolution reaction / selective etching / water splitting

Cite this article

Download citation ▾

Yeonsu Park, Suok Lee, Eunwoo Park, Yong-Hwan Mo, Juwon Lee, Jong Bae Park, Bong Kyun Kang, Younghyun Cho, Gyeong Hee Ryu, Sang-Beom Han, John Hong, Young-Woo Lee. Modulation of a NiFe-Layered Double Hydroxide Electrode Using Zn Doping and Selective Etching Process for High-Performance Oxygen Evolution Reaction. Battery Energy, 2025, 4(4): e70012 DOI:10.1002/bte2.70012

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	S. Mekhilef, R. Saidur, and A. Safari, “Comparative Study of Different Fuel Cell Technologies,” Renewable and Sustainable Energy Reviews 16, no. 1 (2012): 981-989.

[2]	Y. Luo, Y. Wu, C. Huang, C. Menon, S.-P. Feng, and P. K. Chu, “Plasma Modified and Tailored Defective Electrocatalysts for Water Electrolysis and Hydrogen Fuel Cells,” EcoMat 4, no. 4 (2022): e12197.

[3]	H. Jiang, R. Luo, Y. Li, and W. Chen, “Recent Advances in Solid-Liquid-Gas Three-Phase Interfaces in Electrocatalysis for Energy Conversion and Storage,” EcoMat 4, no. 4 (2022): e12199.

[4]	F. Xiao, Y.-C. Wang, Z.-P. Wu, et al., “Recent Advances in Electrocatalysts for Proton Exchange Membrane Fuel Cells and Alkaline Membrane Fuel Cells,” Advanced Materials 33, no. 50 (2021): 2006292.

[5]	M. M. Hossen, M. S. Hasan, M. R. I. Sardar, et al., “State-of-the-Art and Developmental Trends in Platinum Group Metal-Free Cathode Catalyst for Anion Exchange Membrane Fuel Cell (AEMFC),” Applied Catalysis, B: Environment and Energy 325 (2023): 121733.

[6]	X.-L. Liu, Y.-C. Jiang, J.-T. Huang, et al., “Bifunctional PdPt Bimetallenes for Formate Oxidation-Boosted Water Electrolysis,” Carbon Energy 5 (2023): e367.

[7]	R.-T. Liu, Z.-L. Xu, F.-M. Li, et al., “Recent Advances in Proton Exchange Membrane Water Electrolysis,” Chemical Society Reviews 52 (2023): 5652-5683.

[8]	Y. Liu, S. Liu, P. Zhang, et al., “Electronic Structure Regulation of MnCo₂O₄ via Surface-Phosphorization Coupling to Monolithic Carbon for Oxygen Electrocatalysis in Zn-Air Batteries,” Advanced Functional Materials 34 (2024): 2400522.

[9]	J. Zhao, N. Liao, and J. Luo, “Transforming NiFe Layered Double Hydroxide Into NiFeP_x for Efficient Alkaline Water Splitting,” Journal of Materials Chemistry A 11 (2023): 9682-9690.

[10]	A. Mohammadi and M. Mehrpooya, “A Comprehensive Review on Coupling Different Types of Electrolyzer to Renewable Energy Sources,” Energy 158 (2018): 632-655.

[11]	S. Lee, Y. Park, H. Lim, et al., “Bimetallic Metal Organic Framework-Derived Co₉S₈-MoS₂ Nanohybrids as an Efficient Dual Functional Electrocatalyst Towards the Hydrogen and Oxygen Evolution Reactions,” Journal of Industrial and Engineering Chemistry 130 (2024): 317-323.

[12]	X. Lu, Q. Zhang, Y. H. Ng, and C. Zhao, “Reversible Ternary Nickel-Cobalt-Iron Catalysts for Intermittent Water Electrolysis,” EcoMat 2, no. 1 (2020): e12012.

[13]	G. Sriram, K. Dhanabalan, K. V. Ajeya, et al., “Recent Progress in Anion Exchange Membranes (AEMs) in Water Electrolysis: Synthesis, Physio-Chemical Analysis, Properties, and Applications,” Journal of Materials Chemistry A 11, no. 39 (2023): 20886-21008.

[14]	N. Zhang, C. Wang, J. Chen, and Y. Chai, “Oxygen Reactivity Regulation via Double-Exchange Interaction for Enhanced Water Oxidation,” EcoMat 5, no. 2 (2023): e12290.

[15]	Z.-Y. Yu, Y. Duan, X.-Y. Feng, X. Yu, M.-R. Gao, and S.-H. Yu, “Clean and Affordable Hydrogen Fuel From Alkaline Water Splitting: Past, Recent Progress, and Future Prospects,” Advanced Materials 33, no. 31 (2021): 2007100.

[16]	G. Yilmaz, T. Yang, K. J. H. Lim, et al., “Rational Engineering of Metal-Organic Coordination Networks Into Facet-Controlled Phosphides for Overall Water Splitting,” EcoMat 5, no. 3 (2023): e12312.

[17]	Z. Wei, M. Guo, and Q. Zhang, “Scalable Electrodeposition of NiFe-Based Electrocatalysts With Self-Evolving Multi-Vacancies for High-Performance Industrial Water Electrolysis,” Applied Catalysis, B: Environment and Energy 322 (2023): 122101.

[18]	M. Wang, Y. Chen, Z. Yu, et al., “Unraveling the π-Interaction of NiFe-Based Metal-Organic Frameworks With Enhanced Oxygen Evolution: Optimizing Electronic Structure and Facilitating Electron Transfer Modulation,” Journal of Colloid and Interface Science 640 (2023): 1-14.

[19]	M. Gong and H. Dai, “A Mini Review of NiFe-Based Materials as Highly Active Oxygen Evolution Reaction Electrocatalysts,” Nano Research 8 (2015): 23-39.

[20]	Y. Ma, Y. Wang, D. Xie, et al., “NiFe-Layered Double Hydroxide Nanosheet Arrays Supported on Carbon Cloth for Highly Sensitive Detection of Nitrite,” ACS Applied Materials & Interfaces 10, no. 7 (2018): 6541-6551.

[21]	Z. Cai, X. Bu, P. Wang, J. C. Ho, J. Yang, and X. Wang, “Recent Advances in Layered Double Hydroxide Electrocatalysts for the Oxygen Evolution Reaction,” Journal of Materials Chemistry A 7, no. 10 (2019): 5069-5089.

[22]	F. Liao, X. Zhao, G. Yang, Q. Cheng, L. Mao, and L. Chen, “Recent Advances on Two-Dimensional NiFe-LDHs and Their Composites for Electrochemical Energy Conversion and Storage,” Journal of Alloys and Compounds 872 (2021): 159649.

[23]	F. Song and X. Hu, “Exfoliation of Layered Double Hydroxides for Enhanced Oxygen Evolution Catalysis,” Nature Communications 5 (2014): 4477.

[24]	H. Xu, W.-D. Zhang, J. Liu, Y. Yao, X. Yan, and Z.-G. Gu, “Intercalation-Induced Partial Exfoliation of NiFe LDHs With Abundant Active Edge Sites for Highly Enhanced Oxygen Evolution Reaction,” Journal of Colloid and Interface Science 607 (2022): 1353-1361.

[25]	J. Zhang, J. Liu, L. Xi, et al., “Single-Atom Au/NiFe Layered Double Hydroxide Electrocatalyst: Probing the Origin of Activity for Oxygen Evolution Reaction,” Journal of the American Chemical Society 140, no. 11 (2018): 3876-3879.

[26]	W. Zhu, L. Liu, Z. Yue, et al., “Au Promoted Nickel-Iron Layered Double Hydroxide Nanoarrays: A Modular Catalyst Enabling High-Performance Oxygen Evolution,” ACS Applied Materials & Interfaces 9, no. 23 (2017): 19807-19814.

[27]	H. S. Jadhav, A. Roy, B. Z. Desalegan, and J. G. Seo, “An Advanced and Highly Efficient Ce Assisted NiFe-LDH Electrocatalyst for Overall Water Splitting,” Sustainable Energy & Fuels 4, no. 1 (2020): 312-323.

[28]	Y. Kong, Y. Wang, W. Chu, and Z. Liu, “Tailoring Surface and Interface Electronic Structure of NiFe LDH via V Doping for Enhanced Oxygen Evolution Reaction,” Journal of Alloys and Compounds 885 (2021): 160929.

[29]	H. Zhong, T. Liu, S. Zhang, et al., “Template-Free Synthesis of Three-Dimensional NiFe-LDH Hollow Microsphere With Enhanced OER Performance in Alkaline Media,” Journal of Energy Chemistry 33 (2019): 130-137.

[30]	C. Wu, H. Li, Z. Xia, et al., “NiFe Layered Double Hydroxides With Unsaturated Metal Sites via Precovered Surface Strategy for Oxygen Evolution Reaction,” ACS Catalysis 10, no. 19 (2020): 11127-11135.

[31]	B. Zhang, K. Jiang, H. Wang, and S. Hu, “Fluoride-Induced Dynamic Surface Self-Reconstruction Produces Unexpectedly Efficient Oxygen-Evolution Catalyst,” Nano Letters 19, no. 1 (2019): 530-537.

[32]	F. Schipper, M. Dixit, D. Kovacheva, et al., “Stabilizing Nickel-Rich Layered Cathode Materials by a High-Charge Cation Doping Strategy: Zirconium-Doped LiNi_0.6Co_0.2Mn_0.2O₂,” Journal of Materials Chemistry A 4, no. 41 (2016): 16073-16084.

[33]	X. Zeng, Z. Cai, C. Zhang, D. Wang, J. Xu, and X. Wang, “Novel NiFe-LDH@Ni-MOF/NF Heterostructured Electrocatalysts for Efficient Oxygen Evolution,” Materials Research Letters 10, no. 2 (2022): 88-96.

[34]	S. Lee, K. Banjac, M. Lingenfelder, and X. Hu, “Oxygen Isotope Labeling Experiments Reveal Different Reaction Sites for the Oxygen Evolution Reaction on Nickel and Nickel Iron Oxides,” Angewandte Chemie International Edition 58, no. 30 (2019): 10295-10299.

[35]	C. Chen, Y. Zheng, Y. Zhan, X. Lin, Q. Zheng, and K. Wei, “Enhanced Raman Scattering and Photocatalytic Activity of Ag/ZnO Heterojunction Nanocrystals,” Dalton Transactions 40 (2011): 9566-9570.

[36]	A. K. Rana, Y. Kumar, P. Rajput, S. N. Jha, D. Bhattacharyya, and P. M. Shirage, “Search for Origin of Room Temperature Ferromagnetism Properties in Ni-Doped ZnO Nanostructure,” ACS Applied Materials & Interfaces 9, no. 8 (2017): 7691-7700.

[37]

X. Luo, S. Yuan, X. Pan, C. Zhang, S. Du, and Y. Liu, “Synthesis and Enhanced Corrosion Protection Performance of Reduced Graphene Oxide Nanosheet/ZnAl Layered Double Hydroxide Composite Films by Hydrothermal Continuous Flow Method,” ACS Applied Materials & Interfaces 9, no. 21 (2017): 18263-18275.

[38]	Z. Xu, Y. Ying, G. Zhang, et al., “Engineering NiFe Layered Double Hydroxide by Valence Control and Intermediate Stabilization Toward the Oxygen Evolution Reaction,” Journal of Materials Chemistry A 8, no. 48 (2020): 26130-26138.

[39]	J. Jiang, A. Zhang, L. Li, and L. Ai, “Nickel-Cobalt Layered Double Hydroxide Nanosheets as High-Performance Electrocatalyst for Oxygen Evolution Reaction,” Journal of Power Sources 278 (2015): 445-451.

[40]	S. Xie, Y. Yan, S. Lai, et al., “Ni³⁺-Enriched Nickel-Based Electrocatalysts for Superior Electrocatalytic Water Oxidation,” Applied Surface Science 605 (2022): 154743.

[41]	M. Liu, Z. Liu, W. Chen, et al., “NiFe Nanoparticle-Encapsulated Ultrahigh-Oxygen-Doped Carbon Layers as Bifunctional Electrocatalysts for Rechargeable Zn-Air Batteries,” Inorganic Chemistry 62 (2023): 11199-11206.

[42]	J. Li, W. Chen, X. Pi, et al., “N-Doped Pitch Assisted Local Interface Micro-Environment Tailoring and Microcrystalline Regulation in Carbon Nanotube for Efficient Oxygen Reduction Reaction,” Fuel 378 (2024): 133014.

[43]	W. Chen, X. Pi, Z. Qu, et al., “Pyridinic N-B Pair-Doped Carbon Microspheres With Refined Hierarchical Architectures for Rechargeable Zinc-Air Batteries,” Applied Energy 377 (2025): 124511.

[44]	T. Yamashita and P. Hayes, “Analysis of XPS Spectra of Fe²⁺ and Fe³⁺ Ions in Oxide Materials,” Applied Surface Science 254, no. 8 (2008): 2441-2449.

[45]	D. K. Cho, B. Yan, S. J. Park, et al., “Hierarchical Heterogeneous NiFe Layered Double Hydroxides for Efficient Solar-Powered Water Oxidation,” ACS Applied Materials & Interfaces 15, no. 37 (2023): 43933-43941.

[46]	K. B. Lee, S. Jo, H. Choi, Y.-W. Lee, and J. I. Sohn, “Boosting Catalyst Activity With High Valency Metal Species Through Fe Doping on Normal Spinel NiCr₂O₄ for Superior Water Oxidation,” Applied Surface Science 609 (2023): 155326.

[47]	H. Liu, Y. Wang, X. Lu, et al., “The Effects of Al Substitution and Partial Dissolution on Ultrathin NiFeAl Trinary Layered Double Hydroxide Nanosheets for Oxygen Evolution Reaction in Alkaline Solution,” Nano Energy 35 (2017): 350-357.

[48]

W. Jiang, A. Y. Faid, B. F. Gomes, et al., “Composition-Dependent Morphology, Structure, and Catalytical Performance of Nickel-Iron Layered Double Hydroxide as Highly-Efficient and Stable Anode Catalyst in Anion Exchange Membrane Water Electrolysis,” Advanced Functional Materials 32 (2022): 2203520.

[49]	Q. Jiang, S. Wang, C. Zhang, et al., “Active Oxygen Species Mediate the Iron-Promoting Electrocatalysis of Oxygen Evolution Reaction on Metal Oxyhydroxides,” Nature Communications 14 (2023): 6826.

[50]	M. Asnavandi, Y. Yin, Y. Li, C. Sun, and C. Zhao, “Promoting Oxygen Evolution Reactions Through Introduction of Oxygen Vacancies to Benchmark NiFe-OOH Catalysts,” ACS Energy Letters 3 (2018): 1515-1520.

[51]	R. R. Rao, S. Corby, A. Bucci, et al., “Spectroelectrochemical Analysis of the Water Oxidation Mechanism on Doped Nickel Oxides,” Journal of the American Chemical Society 144 (2022): 7622-7633.

[52]	L. Peng, N. Yang, Y. Yang, et al., “Atomic Cation-Vacancy Engineering of Nife-Layered Double Hydroxides for Improved Activity and Stability Towards the Oxygen Evolution Reaction,” Angewandte Chemie International Edition 60 (2021): 24612-24619.