Host–Guest Engineering of Dual-Metal Nitrogen Carbides as Bifunctional Oxygen Electrocatalysts for Long-Cycle Rechargeable Zn-Air Battery

Yisi Liu , Zongxu Li , Yonghang Zeng , Meifeng Liu , Dongbin Xiong , Lina Zhou , Yue Du , Yao Xiao

Carbon Energy ›› 2025, Vol. 7 ›› Issue (4) : e682

PDF
Carbon Energy ›› 2025, Vol. 7 ›› Issue (4) : e682 DOI: 10.1002/cey2.682
RESEARCH ARTICLE

Host–Guest Engineering of Dual-Metal Nitrogen Carbides as Bifunctional Oxygen Electrocatalysts for Long-Cycle Rechargeable Zn-Air Battery

Author information +
History +
PDF

Abstract

The key to obtaining high intrinsic catalytic activity of Me-Nx-C electrocatalysts for Zn-air batteries is to form high-density bifunctional Me-Nx active sites during the pyrolysis of the precursor while maintaining structural stability. In this study, a host–guest spatial confinement strategy was utilized to synthesize a composite catalyst consisting of Co3Fe7 nanoparticles confined in an N-doped carbon network. The coupling between the host (MIL-88B) and guest (cobalt porphyrin, CoPP) produces high-density bimetallic atomic active sites. By controlling the mass of guest molecules, it is possible to construct precursors with the highest activity potential. The Co3Fe7/NC material with a certain amount of the guest displays a better electrocatalytic performance for both oxygen reduction reaction and oxygen evolution reaction with a half-wave potential (E1/2) of 0.85 V and an overpotential of 1.59 V at 10 mA cm−2, respectively. The specific structure of bimetallic active centers is verified to be FeN2-CoN4 using experimental characterizations, and the oxygen reaction mechanism is explored by in-situ characterization techniques and first-principles calculations. The Zn-air battery assembled with Co3Fe7/NC cathode exhibits a remarkable open-circuit voltage of 1.52 V, an exceptional peak power density of 248.1 mW cm−2, and stable cycling stability over 1000 h. Particularly, the corresponding flexible Zn-air battery affords prominent cycling performance under different bending angles. This study supplies the idea and method of designing catalysts with specific structures at the atomic and electronic scales for breaking through the large-scale application of electrocatalysts based on oxygen reactions in fuel cells/metal-air batteries.

Keywords

bifunctional electrocatalytic performance / bimetal active sites / host−guest engineering / MIL-88B / Zn-air battery

Cite this article

Download citation ▾
Yisi Liu, Zongxu Li, Yonghang Zeng, Meifeng Liu, Dongbin Xiong, Lina Zhou, Yue Du, Yao Xiao. Host–Guest Engineering of Dual-Metal Nitrogen Carbides as Bifunctional Oxygen Electrocatalysts for Long-Cycle Rechargeable Zn-Air Battery. Carbon Energy, 2025, 7(4): e682 DOI:10.1002/cey2.682

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]

Y. Li and J. Lu, “Metal-Air Batteries: Will They be the Future Electrochemical Energy Storage Device of Choice?,” ACS Energy Letters 2, no. 6 (2017): 1370-1377.
[2]

M. A. Rahman, X. Wang, and C. Wen, “High Energy Density Metal-Air Batteries: A Review,” Journal of The Electrochemical Society 160, no. 10 (2013): A1759-A1771.
[3]

Y. Zhang, Y. P. Deng, J. Wang, et al., “Recent Progress on Flexible Zn-Air Batteries,” Energy Storage Materials 35 (2021): 538-549.
[4]

J. Pan, Y. Y. Xu, H. Yang, Z. Dong, H. Liu, and B. Y. Xia, “Advanced Architectures and Relatives of Air Electrodes in Zn-Air Batteries,” Advanced Science 5, no. 4 (2018): 1700691.
[5]

D. Lee, H. W. Kim, J. M. Kim, K. H. Kim, and S. Y. Lee, “Flexible/Rechargeable Zn-Air Batteries Based on Multifunctional Heteronanomat Architecture,” ACS Applied Materials & Interfaces 10, no. 26 (2018): 22210-22217.
[6]

M. Shen, C. Wei, K. Ai, and L. Lu, “Transition Metal-Nitrogen-Carbon Nanostructured Catalysts for the Oxygen Reduction Reaction: From Mechanistic Insights to Structural Optimization,” Nano Research 10, no. 5 (2017): 1449-1470.
[7]

G. Zhong, L. Zou, X. Chi, et al., “Atomically Dispersed Mn-Nx Catalysts Derived From Mn-Hexamine Coordination Frameworks for Oxygen Reduction Reaction,” Carbon Energy 6, no. 5 (2024): e484.
[8]

J. Li, S. Ghoshal, W. Liang, et al., “Structural and Mechanistic Basis for the High Activity of Fe-N-C Catalysts Toward Oxygen Reduction,” Energy & Environmental Science 9, no. 7 (2016): 2418-2432.
[9]

L. Lin, Y. Ni, L. Shang, et al., “Atomic-Level Modulation-Induced Electron Redistribution in Co Coordination Polymers Elucidates the Oxygen Reduction Mechanism,” ACS Catalysis 12, no. 13 (2022): 7531-7540.
[10]

C. Tang, L. Chen, H. Li, et al., “Tailoring Acidic Oxygen Reduction Selectivity on Single-Atom Catalysts Via Modification of First and Second Coordination Spheres,” Journal of the American Chemical Society 143 (2021): 7819-7827.
[11]

Y. He, Q. Tan, L. Lu, J. Sokolowski, and G. Wu, “Metal-Nitrogen-Carbon Catalysts for Oxygen Reduction in Pem Fuel Cells: Self-Template Synthesis Approach to Enhancing Catalytic Activity and Stability,” Electrochemical Energy Reviews 2, no. 2 (2019): 231-251.
[12]

J. Guo, C. Y. Lin, Z. Xia, and Z. Xiang, “A Pyrolysis-Free Covalent Organic Polymer for Oxygen Reduction,” Angewandte Chemie International Edition 57, no. 38 (2018): 12567-12572.
[13]

Y. Li, L. Zhang, Y. Han, et al., “Interface Engineering of Bifunctional Oxygen Electrocatalysts for Rechargeable Zn-Air Batteries,” Materials Chemistry Frontiers 7, no. 19 (2023): 4281-4303.
[14]

Y. Yan, H. Cheng, Z. Qu, et al., “Recent Progress on the Synthesis and Oxygen Reduction Applications of Fe-Based Single-Atom and Double-Atom Catalysts,” Journal of Materials Chemistry A 9, no. 35 (2021): 19489-19507.
[15]

X. F. Lu, B. Y. Xia, S. Q. Zang, and X. W. Lou, “Metal-Organic Frameworks Based Electrocatalysts for the Oxygen Reduction Reaction,” Angewandte Chemie International Edition 59, no. 12 (2020): 4634-4650.
[16]

S. Zheng, X. Li, B. Yan, et al., “Transition-Metal (Fe, Co, Ni) Based Metal-Organic Frameworks for Electrochemical Energy Storage,” Advanced Energy Materials 7, no. 18 (2017): 1602733.
[17]

E. G. Derouane and C. D. Chang, “Confinement Effects in the Adsorption of Simple Bases by Zeolites,” Microporous and Mesoporous Materials 35-36 (2000): 425-433.
[18]

X. Zhou, J. Gao, Y. Hu, et al., “Theoretically Revealed and Experimentally Demonstrated Synergistic Electronic Interaction of Cofe Dual-Metal Sites on N-Doped Carbon for Boosting Both Oxygen Reduction and Evolution Reactions,” Nano Letters 22, no. 8 (2022): 3392-3399.
[19]

A. Shahraei, I. Martinaiou, K. A. Creutz, et al., “Exploring Active Sites in Multi-Heteroatom-Doped Co-Based Catalysts for Hydrogen Evolution Reactions,” Chemistry—A European Journal 24, no. 48 (2018): 12480-12484.
[20]

H. He, Y. Wang, J. Li, et al., “Confined Conductive and Light-Adsorbed Network in Metal Organic Frameworks (MIL-88B(Fe)) With Enhanced Photo-Fenton Catalytic Activity for Sulfamethoxazole Degradation,” Chemical Engineering Journal 427 (2022): 131962.
[21]

C. Casiraghi, A. C. Ferrari, and J. Robertson, “Raman Spectroscopy of Hydrogenated Amorphous Carbons,” Physical Review B 72, no. 8 (2005): 085401.
[22]

J. Tang, R. R. Salunkhe, J. Liu, et al., “Thermal Conversion of Core-Shell Metal-Organic Frameworks: A New Method for Selectively Functionalized Nanoporous Hybrid Carbon,” Journal of the American Chemical Society 137, no. 4 (2015): 1572-1580.
[23]

S. S. A. Shah, L. Peng, T. Najam, et al., “Monodispersed Co in Mesoporous Polyhedrons: Fine-Tuning of ZIF-8 Structure With Enhanced Oxygen Reduction Activity,” Electrochimica Acta 251 (2017): 498-504.
[24]

M. Jiang, C. Fu, R. Cheng, et al., “Integrated and Binder-Free Air Cathodes of Co3Fe7 Nanoalloy and Co5.47N Encapsulated in Nitrogen-Doped Carbon Foam With Superior Oxygen Reduction Activity in Flexible Alumnum-Air Batteries,” Advanced Science 7, no. 18 (2020): 2000747.
[25]

M. Liu, Q. Xu, Q. Miao, et al., “Atomic Co-N4 and Co Nanoparticles Confined in COF@ZIF-67 Derived Core-Shell Carbon Frameworks: Bifunctional Non-Precious Metal Catalysts Toward the ORR and HER,” Journal of Materials Chemistry A 10, no. 1 (2022): 228-233.
[26]

Q. He, Q. Li, S. Khene, et al., “High-Loading Cobalt Oxide Coupled With Nitrogen-Doped Graphene for Oxygen Reduction in Anion-Exchange-Membrane Alkaline Fuel Cells,” Journal of Physical Chemistry C 117, no. 17 (2013): 8697-8707.
[27]

Y. W. Ju, S. Yoo, C. Kim, et al., “Fe@N-Graphene Nanoplatelet-Embedded Carbon Nanofibers as Efficient Electrocatalysts for Oxygen Reduction Reaction,” Advanced Science 3, no. 1 (2016): 1500205.
[28]

X. Bao, Y. Gong, J. Deng, S. Wang, and Y. Wang, “Organic-Acid-Assisted Synthesis of a 3D Lasagna-Like Fe-N-Doped CNTs-G Framework: An Efficient and Stable Electrocatalyst for Oxygen Reduction Reactions,” Nano Research 10, no. 4 (2016): 1258-1267.
[29]

W. Zhu, Y. Pei, J. C. Douglin, et al., “Multi-Scale Study on Bifunctional Co/Fe-N-C Cathode Catalyst Layers With High Active Site Density for the Oxygen Reduction Reaction,” Applied Catalysis B: Environmental 299 (2021): 120656.
[30]

B. Wang, L. Xu, G. Liu, et al., “In Situ Confinement Growth of Peasecod-Like N-Doped Carbon Nanotubes Encapsulate Bimetallic Fecu Alloy as a Bifunctional Oxygen Reaction Cathode Electrocatalyst for Sustainable Energy Batteries,” Journal of Alloys and Compounds 826 (2020): 154152.
[31]

Z. Li, H. He, H. Cao, et al., “Atomic Co/Ni Dual Sites and Co/Ni Alloy Nanoparticles in N-Doped Porous Janus-Like Carbon Frameworks for Bifunctional Oxygen Electrocatalysis,” Applied Catalysis B: Environmental 240 (2019): 112-121.
[32]

Y. Fu, H. Y. Yu, C. Jiang, et al., “NiCo Alloy Nanoparticles Decorated on N-Doped Carbon Nanofibers as Highly Active and Durable Oxygen Electrocatalyst,” Advanced Functional Materials 28, no. 9 (2018): 1705094.
[33]

S. Sarkar, A. Biswas, E. E. Siddharthan, R. Thapa, and R. S. Dey, “Strategic Modulation of Target-Specific Isolated Fe,Co Single-Atom Active Sites for Oxygen Electrocatalysis Impacting High Power Zn-Air Battery,” ACS Nano 16, no. 5 (2022): 7890-7903.
[34]

Y. He, X. Yang, Y. Li, et al., “Atomically Dispersed Fe-Co Dual Metal Sites as Bifunctional Oxygen Electrocatalysts for Rechargeable and Flexible Zn-Air Batteries,” ACS Catalysis 12 (2022): 1216-1227.
[35]

H. Zhang, M. Zhao, H. Liu, et al., “Ultrastable FeCo Bifunctional Electrocatalyst on Se-Doped CNTs for Liquid and Flexible All-Solid-State Rechargeable Zn-Air Batteries,” Nano Letters 21, no. 5 (2021): 2255-2264.
[36]

Z. Wang, X. Jin, C. Zhu, et al., “Atomically Dispersed Co2-N6 and Fe-N4 Costructures Boost Oxygen Reduction Reaction in Both Alkaline and Acidic Media,” Advanced Materials 33, no. 49 (2021): 2104718.
[37]

Y. Liu, Z. Chen, Z. Li, et al., “CoNi Nanoalloy-Co-N4 Composite Active Sites Embedded in Hierarchical Porous Carbon as Bi-Functional Catalysts for Flexible Zn-Air Battery,” Nano Energy 99 (2022): 107325.
[38]

Y. Wang, K. Liu, J. Li, et al., “CoN4 Active Sites in Locally Distorted Carbon Structure for Efficient Oxygen Reduction Reaction Via Regulating Coordination Environment,” Chemical Engineering Journal 429 (2022): 132119.
[39]

Y. He, Q. Shi, W. Shan, et al., “Dynamically Unveiling Metal-Nitrogen Coordination During Thermal Activation to Design High-Efficient Atomically Dispersed CoN4 Active Sites,” Angewandte Chemie International Edition 60, no. 17 (2021): 9516-9526.
[40]

J. C. Hu, M. X. Gui, W. Xia, et al., “Facile Formation of CoN4 Active Sites Onto a SiO2 Support to Achieve Robust CO2 and Proton Reduction in a Noble-Metal-Free Photocatalytic System,” Journal of Materials Chemistry A 7, no. 17 (2019): 10475-10482.
[41]

Y. He, S. Hwang, D. A. Cullen, et al., “Highly Active Atomically Dispersed CoN4 Fuel Cell Cathode Catalysts Derived From Surfactant-Assisted MOFs: Carbon-Shell Confinement Strategy,” Energy & Environmental Science 12, no. 1 (2019): 250-260.
[42]

J. Li, T. Lu, Y. Fang, et al., “The Manipulation of Rectifying Contact of Co and Nitrogen-Doped Carbon Hierarchical Superstructures Toward High-Performance Oxygen Reduction Reaction,” Carbon Energy 6, no. 9 (2024): e529.
[43]

X. Zhao, J. Chen, Z. Bi, et al., “Electron Modulation and Morphology Engineering Jointly Accelerate Oxygen Reaction to Enhance Zn-Air Battery Performance,” Advanced Science 10, no. 8 (2023): 2205889.
[44]

X. Xu, S. Wang, S. Guo, et al., “Cobalt Phosphosulfide Nanoparticles Encapsulated Into Heteroatom-Doped Carbon as Bifunctional Electrocatalyst for Zn−Air Battery,” Advanced Powder Materials 1, no. 3 (2022): 100027.
[45]

S. Yang, F. Jiao, and Y. Gong, “Electrochemical Crystalline/Amorphous Ni(OH)S@CoFe-LDH/NF for Efficient Oxygen Evolution Reaction,” Separation and Purification Technology 331 (2024): 125716.
[46]

X. Li, Z. Su, Z. Zhao, Q. Cai, Y. Li, and J. Zhao, “Single Ir Atom Anchored in Pyrrolic-N4 Doped Graphene as a Promising Bifunctional Electrocatalyst for the ORR/OER: A Computational Study,” Journal of Colloid and Interface Science 607 (2022): 1005-1013.
[47]

H. Li, Y. Wen, M. Jiang, et al., “Understanding of Neighboring Fe-N4-C and Co-N4-C Dual Active Centers for Oxygen Reduction Reaction,” Advanced Functional Materials 31, no. 22 (2021): 2011289.
[48]

C. F. Li, J. W. Zhao, L. Xie, J. Q. Wu, and G. R. Li, “Water Adsorption and Dissociation Promoted by Co*-/N-C*-Biactive Sites of Metallic Co/N-Doped Carbon Hybrids for Efficient Hydrogen Evolution,” Applied Catalysis B: Environmental 282 (2021): 119463.

RIGHTS & PERMISSIONS

2025 The Author(s). Carbon Energy published by Wenzhou University and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF

13

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/