High-Performance NiCu Hydroxide Self-Supported Electrode as a Bifunctional Catalyst for AOR and OER

Yanchao Liu; Yin Cai; Zhongmei Yang; Yue Shen; Xiaoyang Wang; Xiaoou Song; Xiaojiang Mu; Jie Gao; Jianhua Zhou; Lei Miao

doi:10.1002/bte2.70010

Battery Energy ›› 2025, Vol. 4 ›› Issue (4) :e70010 DOI: 10.1002/bte2.70010

RESEARCH ARTICLE

High-Performance NiCu Hydroxide Self-Supported Electrode as a Bifunctional Catalyst for AOR and OER

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Abstract

Ammonia has gained considerable attention as a promising energy carrier due to its high hydrogen content, carbon-free emissions, and ease of storage and transportation compared to hydrogen gas. The electrochemical ammonia oxidation reaction (AOR) is a pivotal process for harnessing ammonia as a sustainable energy source, enabling hydrogen production through ammonia decomposition or electricity generation via direct ammonia fuel cells. NiCu, a transition metal alloy, has shown great potential as an efficient and cost-effective catalyst for AOR. In this study, high-valence Ni and Cu hydroxyl hydroxides were synthesized on nickel foam to form NiCuOOH in the structure of folded nanosheets, serving as an anodic electrocatalyst for AOR. Comprehensive characterization identified high-valence metals as the primary active components. By optimizing the Ni/Cu ratio, the catalyst achieved remarkable performance and stability, reaching a maximum current density of 169 mA cm^-² at 1.62 V versus RHE, with 0.16 at% Cu delivering high ammonia oxidation activity, and being stable for 48 h at 100 mA cm^-2. Additionally, the catalyst exhibited excellent catalytic activity for the oxygen evolution reaction (OER), attaining a maximum current density of 152 mA cm^-2 at 1.72 V versus RHE. This study presents a cost-effective, high-performance, and easily synthesized bifunctional self-supporting catalyst, offering significant potential for both AOR and OER applications.

Keywords

ammonia oxidation reaction (AOR) / bifunctional catalyst / NiCu hydroxide nanosheets / oxygen evolution reaction (OER)

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Yanchao Liu, Yin Cai, Zhongmei Yang, Yue Shen, Xiaoyang Wang, Xiaoou Song, Xiaojiang Mu, Jie Gao, Jianhua Zhou, Lei Miao. High-Performance NiCu Hydroxide Self-Supported Electrode as a Bifunctional Catalyst for AOR and OER. Battery Energy, 2025, 4(4): e70010 DOI:10.1002/bte2.70010

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References

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[1]	H. Balat and E. Kırtay, “Hydrogen From Biomass-Present Scenario and Future Prospects,” International Journal of Hydrogen Energy 35, no. 14 (2010): 7416-7426.

[2]	Z. Fan, W. Weng, J. Zhou, D. Gu, and W. Xiao, “Catalytic Decomposition of Methane to Produce Hydrogen: A Review,” Journal of Energy Chemistry 58 (2021): 415-430.

[3]	U. Eberle, M. Felderhoff, and F. Schüth, “Chemical and Physical Solutions for Hydrogen Storage,” Angewandte Chemie International Edition 48, no. 36 (2009): 6608-6630.

[4]	M. R. Usman, “Hydrogen Storage Methods: Review and Current Status,” Renewable and Sustainable Energy Reviews 167 (2022): 112743.

[5]	B. L. Salvi and K. A. Subramanian, “Sustainable Development of Road Transportation Sector Using Hydrogen Energy System,” Renewable and Sustainable Energy Reviews 51 (2015): 1132-1155.

[6]	K. Zhu, H. Jiang, G.-F. Chen, H. Wu, L. X. Ding, and H. Wang, “Simultaneous Electrosynthesis of Nitrate and Hydrogen by Integrating Ammonia Oxidation and Water Reduction,” Chinese Journal of Catalysis 55 (2023): 216-226.

[7]	Y. Wang, T. Wang, H. Arandiyan, et al., “Advancing Catalysts by Stacking Fault Defects for Enhanced Hydrogen Production: A Review,” Advanced Materials 36 (2024): 2313378.

[8]	T. F. Qahtan, I. O. Alade, M. S. Rahaman, and T. A. Saleh, “Mapping the Research Landscape of Hydrogen Production Through Electrocatalysis: A Decade of Progress and Key Trends,” Renewable and Sustainable Energy Reviews 184 (2023): 113490.

[9]	H. Ishaq and C. Crawford, “Review of Ammonia Production and Utilization: Enabling Clean Energy Transition and Net-Zero Climate Targets,” Energy Conversion and Management 300 (2024): 117869.

[10]	X. Wang, T. Liang, Z. Zheng, et al., “Mof-Silica Hybrid Derived High Performance K-Cu# SiO₂ Catalyst for Furfural Valorization: The Functional Role of Potassium Acetate (KAc) in Hybridization and Copper Electronic State,” Applied Catalysis A: General 640 (2022): 118603.

[11]	Z.-H. Lyu, J. Fu, T. Tang, J. Zhang, and J.-S. Hu, “Design of Ammonia Oxidation Electrocatalysts for Efficient Direct Ammonia Fuel Cells,” EnergyChem 5, no. 3 (2023): 100093.

[12]	T. Van Nguyen, M. Tekalgne, T. P. Nguyen, Q. Van Le, S. H. Ahn, and S. Y. Kim, “Electrocatalysts Based on MoS₂ and WS₂ for Hydrogen Evolution Reaction: An Overview,” Battery Energy 2, no. 3 (2023): 20220057.

[13]	X. Deng, Z. Jiang, Y. Chen, et al., “Renewable Wood-Derived Hierarchical Porous, N-Doped Carbon Sheet as a Robust Self-Supporting Cathodic Electrode for Zinc-Air Batteries,” Chinese Chemical Letters 34, no. 1 (2023): 107389.

[14]	X. Xu, F. Qiao, Y. Liu, and W. Liu, “Preparation of Cu(OH)₂/Cu₂S Arrays for Enhanced Hydrogen Evolution Reaction,” Battery Energy 3, no. 3 (2024): 20230060.

[15]	Y. Yang, J. Kim, H. Jo, et al., “A Rigorous Electrochemical Ammonia Electrolysis Protocol With In Operando Quantitative Analysis,” Journal of Materials Chemistry A 9, no. 19 (2021): 11571-11579.

[16]	H. Yoon, B. Ju, and D. W. Kim, “Perspectives on the Development of Highly Active, Stable, and Cost-Effective OER Electrocatalysts in Acid,” Battery Energy 2, no. 5 (2023): 20230017.

[17]	R. S. Mane, S. Mane, V. Somkuwar, N. V. Thombre, A. V. Patwardhan, and N. Jha, “A Novel Hierarchically Hybrid Structure of MXene and Bi-Ligand ZIF-67 Based Trifunctional Electrocatalyst for Zinc-Air Battery and Water Splitting,” Battery Energy 2, no. 5 (2023): 20230019.

[18]	J. Mohammed-Ibrahim and X. Sun, “Recent Progress on Earth Abundant Electrocatalysts for Hydrogen Evolution Reaction (HER) in Alkaline Medium to Achieve Efficient Water Splitting—A Review,” Journal of Energy Chemistry 34 (2019): 111-160.

[19]	H. Yin, F. Rong, and Y. Xie, “A Review of Typical Transition Metal Phosphides Electrocatalysts for Hydrogen Evolution Reaction,” International Journal of Hydrogen Energy 52 (2024): 350-375.

[20]	X. Yang, W. Liu, S. Su, et al., “Carbon-Coated Nickel Phosphide With Enriched Surface Ni^δ+ Sites Enables an Exceptionally High Productivity of 2-Methylfuran From Biomass Upgrading,” Catalysis Science & Technology 14 (2024): 3473.

[21]	Y. Zhang, J. Huang, and Y. Lai, “Recent Advances of Ammoxidation in Clean Energy Exploitation and Sewage Purification: A Mini Review,” Chinese Journal of Catalysis 54 (2023): 161-177.

[22]	E. Moran, C. Cattaneo, H. Mishima, et al., “Ammonia Oxidation on Electrodeposited Pt-Ir Alloys,” Journal of Solid State Electrochemistry 12 (2008): 583-589.

[23]	X. Lin, X. Zhang, Z. Wang, et al., “Hyperbranched Concave Octahedron of PtIrCu Nanocrystals With High-Index Facets for Efficiently Electrochemical Ammonia Oxidation Reaction,” Journal of Colloid and Interface Science 601 (2021): 1-11.

[24]	Y. Kang, W. Wang, J. Li, C. Hua, S. Xue, and Z. Lei, “High Performance Ptxeu Alloys as Effective Electrocatalysts for Ammonia Electro-Oxidation,” International Journal of Hydrogen Energy 42, no. 30 (2017): 18959-18967.

[25]	Q. Xue, Y. Zhao, J. Zhu, et al., “PtRu Nanocubes as Bifunctional Electrocatalysts for Ammonia Electrolysis,” Journal of Materials Chemistry A 9, no. 13 (2021): 8444-8451.

[26]	E. P. Bonnin, E. J. Biddinger, and G. G. Botte, “Effect of Catalyst on Electrolysis of Ammonia Effluents,” Journal of Power Sources 182, no. 1 (2008): 284-290.

[27]	M. H. M. T. Assumpção, R. M. Piasentin, P. Hammer, et al., “Oxidation of Ammonia Using PtRh/C Electrocatalysts: Fuel Cell and Electrochemical Evaluation,” Applied Catalysis B: Environment and Energy 174-175 (2015): 136-144.

[28]	X. Xi, Y. Fan, K. Zhang, et al., “Carbon-Free Sustainable Energy Technology: Electrocatalytic Ammonia Oxidation Reaction,” Chemical Engineering Journal 435 (2022): 134818.

[29]	Y. Li, X. Li, H. S. Pillai, et al., “Ternary PtIrNi Catalysts for Efficient Electrochemical Ammonia Oxidation,” ACS Catalysis 10, no. 7 (2020): 3945-3957.

[30]	Y. Tian, H. Tan, X. Li, et al., “Metal-Based Electrocatalysts for Ammonia Electro-Oxidation Reaction to Nitrate/Nitrite: Past, Present, and Future,” Chinese Journal of Catalysis 56 (2024): 25-50.

[31]	L. Wang, K. Jiang, Z. Wang, T. Li, D. Wang, and Y. Q. Liu, “Enabling Surface Reconstruction Through a Heterostructured Ni₃S₄@ NiCo₂O₄/NF Towards Efficient Ammonia Oxidation Reaction,” Chemical Engineering Journal 492 (2024): 152268.

[32]	K. Yao and Y. F. Cheng, “Investigation of the Electrocatalytic Activity of Nickel for Ammonia Oxidation,” Materials Chemistry and Physics 108, no. 2/3 (2008): 247-250.

[33]	A. Kapałka, A. Cally, S. Neodo, C. Comninellis, M. Wächter, and K. M. Udert, “Electrochemical Behavior of Ammonia at Ni/Ni(OH)₂ Electrode,” Electrochemistry Communications 12, no. 1 (2010): 18-21.

[34]	F. Almomani and M. Ali H Salah Saad, “Electrochemical Oxidation of Ammonia (NH₄₊/NH₃) on Synthesized Nickel-Cobalt Oxide Catalyst,” International Journal of Hydrogen Energy 46, no. 6 (2021): 4678-4690.

[35]	Y.-J. Shih and C.-H. Hsu, “Kinetics and Highly Selective N₂ Conversion of Direct Electrochemical Ammonia Oxidation in an Undivided Cell Using NiCo Oxide Nanoparticle as the Anode and Metallic Cu/Ni Foam as the Cathode,” Chemical Engineering Journal 409 (2021): 128024.

[36]	M. Zhu, Y. Yang, S. Xi, et al., “Deciphering NH₃ Adsorption Kinetics in Ternary Ni-Cu-Fe Oxyhydroxide Toward Efficient Ammonia Oxidation Reaction,” Small 17, no. 7 (2021): 2005616.

[37]	J. Hou, Y. Cheng, H. Pan, and P. Kang, “Tailored Bimetallic Ni-Sn Catalyst for Electrochemical Ammonia Oxidation to Dinitrogen With High Selectivity,” Inorganic Chemistry 62, no. 9 (2023): 3986-3992.

[38]	H. Zhang, H. Wang, L. Zhou, et al., “Efficient and Highly Selective Direct Electrochemical Oxidation of Ammonia to Dinitrogen Facilitated by NiCu Diatomic Site Catalysts,” Applied Catalysis B: Environment and Energy 328 (2023): 122544.

[39]	H. K. Vu, T. Mahvelati-Shamsabadi, T. T. Dang, S. H. Hur, S. G. Kang, and J. S. Chung, “Synergistic Effects of Ni and Cu in Morphology-Controlled NiCu Electrocatalysts for Ammonia Electro-Oxidation,” ACS Applied Nano Materials 6, no. 22 (2023): 20688-20699.

[40]	H. Zhang, W. Chen, H. Wang, et al., “A Core-Shell NiCu@NiCuOOH 3D Electrode Induced by Surface Electrochemical Reconstruction for the Ammonia Oxidation Reaction,” International Journal of Hydrogen Energy 47, no. 36 (2022): 16080-16091.

[41]	W. Xu, R. Lan, D. Du, et al., “Directly Growing Hierarchical Nickel-Copper Hydroxide Nanowires on Carbon Fibre Cloth for Efficient Electrooxidation of Ammonia,” Applied Catalysis B: Environment and Energy 218 (2017): 470-479.

[42]	W. Xu, D. Du, R. Lan, et al., “Electrodeposited NiCu Bimetal on Carbon Paper as Stable Non-Noble Anode for Efficient Electrooxidation of Ammonia,” Applied Catalysis B: Environment and Energy 237 (2018): 1101-1109.

[43]	J. Huang, J. Cai, and J. Wang, “Nanostructured Wire-in-Plate Electrocatalyst for High-Durability Production of Hydrogen and Nitrogen From Alkaline Ammonia Solution,” ACS Applied Energy Materials 3, no. 5 (2020): 4108-4113.

[44]	Y. Zhang, D. Ma, Y. Lei, et al., “Markedly Enhanced Hydrogen Production in Wastewater via Ammonia-Mediated Metal Oxyhydroxides Active Sites on Bifunctional Electrocatalysts,” Nano Energy 117 (2023): 108896.

[45]	H. Wang, X. Tong, L. Zhou, et al., “Unique Three-Dimensional Nanoflower-Like NiCu Electrodes Constructed by Co, S Co-Doping for Efficient Ammonia Oxidation Reaction,” Separation and Purification Technology 303 (2022): 122293.

[46]	A. Ashok Kashale, C.-T. Wu, H.-F. Hsu, and I. W. Peter Chen, “In-Situ Monitoring Intermediate Stages in Ammonia Oxidation Reaction via High Performance NiCuBO_x-1/NF Electrocatalysts,” Chemical Engineering Journal 474 (2023): 145907.

[47]	Y.-F. Li, J.-L. Li, and Z.-P. Liu, “Structure and Catalysis of NiOOH: Recent Advances on Atomic Simulation,” Journal of Physical Chemistry C 125, no. 49 (2021): 27033-27045.

[48]	Y. Wang, M. Xu, X. Wang, et al., “Unraveling the Potential-Dependent Structure Evolution in CuO for Electrocatalytic Biomass Valorization,” Science Bulletin 68, no. 23 (2023): 2982-2992.

[49]	X. Pang, H. Bai, Y. Huang, H. Zhao, G. Zheng, and W. Fan, “Mechanistic Insights for Dual-Species Evolution Toward 5-Hydroxymethylfurfural Oxidation,” Journal of Catalysis 417 (2023): 22-34.

[50]	Y.-H. Fang and Z.-P. Liu, “Tafel Kinetics of Electrocatalytic Reactions: From Experiment to First-Principles,” ACS Catalysis 4, no. 12 (2014): 4364-4376.