FeMnOx-Graphene Composites as High-Performance Bifunctional Electrocatalysts for Rechargeable Zinc-Air Batteries

Francisco J. Pérez-Alonso; Alejandra García-Gómez; Elisa Peña; Sara Ruiz-Martinez-Alcocer; Aroa R. Mainar; J. Alberto Blázquez; E. Iruin; Álvaro García; María Retuerto; Sergio Rojas

doi:10.1002/bte2.20250051

Battery Energy ›› 2026, Vol. 5 ›› Issue (1) :e70064 DOI: 10.1002/bte2.20250051

RESEARCH ARTICLE

FeMnO_x-Graphene Composites as High-Performance Bifunctional Electrocatalysts for Rechargeable Zinc-Air Batteries

Author information +

History +

PDF

Abstract

The development of efficient, stable, and cost-effective bifunctional electrocatalysts, particularly those based on earth-abundant elements, is essential for the advancement and large-scale deployment of rechargeable zinc–air batteries (ZABs). In this study, we report the synthesis and electrochemical evaluation of FeMnOx–graphene composites as bifunctional catalysts for the oxygen reduction (ORR) and oxygen evolution reactions (OER). Three catalysts were prepared using a patented process by Gnanomat SL with different graphene nanoplatelets of different physicochemical properties and characterized through XRD, TEM, STEM-EDS, XPS, TGA, and BET analyses. All samples exhibited poor crystallinity and, according to XPS analysis, showed similar surface phases attributed to Fe₂O₃ or Fe³⁺ oxyhydroxide species and Mn₃O₄. Meanwhile, the graphene support influenced the final surface area and oxide dispersion of the composite. Electrochemical testing using a three-electrode system revealed that FeMn-graphene composites, synthesized with high-surface-area graphene, exhibit promising bifunctional activity for both the ORR and OER. Full-cell ZAB testing confirmed improved charge-discharge performance and excellent cycling stability over 500 h at 10 mA cm^-2. These findings highlight the potential of FeMnOx–graphene composites as sustainable and efficient bifunctional air electrodes, providing an attractive alternative to bifunctional catalysts based on critical elements like Co.

Keywords

bifunctional electrocatalysts / graphene / oxygen evolution / oxygen reduction / Zinc-air batteries

Cite this article

Download citation ▾

Francisco J. Pérez-Alonso, Alejandra García-Gómez, Elisa Peña, Sara Ruiz-Martinez-Alcocer, Aroa R. Mainar, J. Alberto Blázquez, E. Iruin, Álvaro García, María Retuerto, Sergio Rojas. FeMnO_x-Graphene Composites as High-Performance Bifunctional Electrocatalysts for Rechargeable Zinc-Air Batteries. Battery Energy, 2026, 5(1): e70064 DOI:10.1002/bte2.20250051

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]	J. A. Blázquez, A. R. Mainar, and E. Iruin, Battery Technologies: Materials and Components (Wiley, 2022), 229-268.

[2]	X. Bi, Y. Jiang, R. Chen, et al., “Rechargeable Zinc–Air versus Lithium–Air Battery: From Fundamental Promises Toward Technological Potentials,” Advanced Energy Materials14 (2024): 2302388, https://doi.org/10.1002/aenm.202302388.

[3]	K. Zeng, X. Zheng, C. Li, et al., “Recent Advances in Non-Noble Bifunctional Oxygen Electrocatalysts Toward Large-Scale Production,” Advanced Functional Materials30 (2020): 2000503, https://doi.org/10.1002/adfm.202000503.

[4]	E. V. Timofeeva, C. U. Segre, G. S. Pour, M. Vazquez, and B. L. Patawah, “Aqueous Air Cathodes and Catalysts for Metal–Air Batteries,” Current Opinion in Electrochemistry38 (2023): 101246, https://doi.org/10.1016/j.coelec.2023.101246.

[5]	H. Y. Jung, S. Park, and B. N. Popov, “Electrochemical Studies of an Unsupported Ptir Electrocatalyst as a Bifunctional Oxygen Electrode in a Unitized Regenerative Fuel Cell,” Journal of Power Sources191 (2009): 357-361.

[6]	Y. Li, M. Gong, Y. Liang, et al., “Advanced Zinc-Air Batteries Based on High-Performance Hybrid Electrocatalysts,” Nature Communications4 (2013): 1805, https://doi.org/10.1038/ncomms2812.

[7]	Y. Q. Zhang, M. Li, B. Hua, Y. Wang, Y. F. Sun, and J. L. Luo, “A Strongly Cooperative Spinel Nanohybrid as an Efficient Bifunctional Oxygen Electrocatalyst for Oxygen Reduction Reaction and Oxygen Evolution Reaction,” Applied Catalysis, B: Environmental236 (2018): 413-419.

[8]	A. R. Mainar, J. A. Blázquez, D. Frattini, et al., “High Performance Carbon Free Bifunctional Air Electrode for Advanced Zinc-Air Batteries,” Electrochimica Acta446 (2023): 142075, https://doi.org/10.1016/j.electacta.2023.142075.

[9]	X. Zou, M. Tang, Q. Lu, Y. Wang, Z. Shao, and L. An, “Carbon-Based Electrocatalysts for Rechargeable Zn–Air Batteries: Design Concepts, Recent Progress and Future Perspectives,” Energy & Environmental Science17 (2024): 386-424.

[10]	J. Ruppert, L. Stegemann, A. Bauer, et al., “Competitive Rechargeable Zinc Batteries for Energy Storage,” Advanced Energy Materials15 (2025): e02866, https://doi.org/10.1002/aenm.202502866.

[11]	Y. Song, W. Li, K. Zhang, C. Han, and A. Pan, “Progress on Bifunctional Carbon-Based Electrocatalysts for Rechargeable Zinc–Air Batteries Based on Voltage Difference Performance,” Advanced Energy Materials14 (2024): 2303352, https://doi.org/10.1002/aenm.202303352.

[12]

M. Mechili, C. Vaitsis, N. Argirusis, P. K. Pandis, G. Sourkouni, and C. Argirusis, “Research Progress in Transition Metal Oxide Based Bifunctional Electrocatalysts for Aqueous Electrically Rechargeable Zinc-Air Batteries,” Renewable and Sustainable Energy Reviews156 (2022): 111970, https://doi.org/10.1016/j.rser.2021.111970.

[13]	Y. Ran, C. Xu, D. Ji, H. Zhao, L. Li, and Y. Lei, “Research Progress of Transition Metal Compounds as Bifunctional Catalysts for Zinc-Air Batteries,” Nano Research Energy3 (2024): e9120092, https://doi.org/10.26599/NRE.2023.9120092.

[14]	N. I. Villanueva-Martínez, C. Alegre, I. Martínez-Visús, and M. J. Lázaro, “Bifunctional Oxygen Electrocatalysts Based on Non-Critical Raw Materials: Carbon Nanostructures and Iron-Doped Manganese Oxide Nanowires,” Catalysis Today420 (2023): 114083, https://doi.org/10.1016/j.cattod.2023.114083.

[15]	P. C. Li, C. C. Hu, T. H. You, and P. Y. Chen, “Development and Characterization of Bi-Functional Air Electrodes for Rechargeable Zinc-Air Batteries: Effects of Carbons,” Carbon111 (2017): 813-821.

[16]

D. M. Morales, M. A. Kazakova, M. Purcel, J. Masa, and W. Schuhmann, “The Sum Is More Than Its Parts: Stability of Mnfe Oxide Nanoparticles Supported on Oxygen-Functionalized Multi-Walled Carbon Nanotubes at Alternating Oxygen Reduction Reaction and Oxygen Evolution Reaction Conditions,” Journal of Solid State Electrochemistry24 (2020): 2901-2906.

[17]

D. M. Morales, M. A. Kazakova, S. Dieckhöfer, et al., “Trimetallic Mn-Fe-Ni Oxide Nanoparticles Supported on Multi-Walled Carbon Nanotubes as High-Performance Bifunctional ORR/OER Electrocatalyst in Alkaline Media,” Advanced Functional Materials30 (2020): 1905992, https://doi.org/10.1002/adfm.201905992.

[18]	M. Liu, R. Zhang, and W. Chen, “Graphene-Supported Nanoelectrocatalysts for Fuel Cells: Synthesis, Properties, and Applications,” Chemical Reviews114 (2014): 5117-5160.

[19]	J. Deng, S. Fang, Y. Fang, Q. Hao, L. Wang, and Y. H. Hu, “Multiple Roles of Graphene in Electrocatalysts for Metal-Air Batteries,” Catalysis Today409 (2023): 2-22.

[20]	C. Domínguez, F. J. Pérez-Alonso, M. A. Salam, et al., “Repercussion of the Carbon Matrix for the Activity and Stability of Fe/N/C Electrocatalysts for the Oxygen Reduction Reaction,” Applied Catalysis, B: Environmental183 (2016): 185-196.

[21]	A. R. Mainar, E. Iruin, L. C. Colmenares, J. A. Blázquez, and H. J. Grande, “Systematic Cycle Life Assessment of a Secondary Zinc–Air Battery as a Function of the Alkaline Electrolyte Composition,” Energy Science & Engineering6 (2018): 174-186.

[22]	T. Yamashita and P. Hayes, “Analysis of XPS Spectra of Fe²⁺ and Fe³⁺ Ions in Oxide Materials,” Applied Surface Science254 (2008): 2441-2449.

[23]	D. D. Hawn and B. M. DeKoven, “Deconvolution as a Correction for Photoelectron Inelastic Energy Losses in the Core Level XPS Spectra of Iron Oxides,” Surface and Interface Analysis10 (1987): 63-74.

[24]	A. Moses Ezhil Raj, S. G. Victoria, V. B. Jothy, et al., “XRD and XPS Characterization of Mixed Valence Mn3O4 Hausmannite Thin Films Prepared by Chemical Spray Pyrolysis Technique,” Applied Surface Science256 (2010): 2920-2926.

[25]	J. Wang, Z. Wu, L. Han, R. Lin, H. L. Xin, and D. Wang, “Hollow-Structured Carbon-Supported Nickel Cobaltite Nanoparticles as an Efficient Bifunctional Electrocatalyst for the Oxygen Reduction and Evolution Reactions,” ChemCatChem8 (2016): 736-742.

[26]	Q. Wang, S. Kaushik, X. Xiao, and Q. Xu, “Sustainable Zinc–Air Battery Chemistry: Advances, Challenges and Prospects,” Chemical Society Reviews52 (2023): 6139-6190.