From elemental metals to synergistic electrocatalysis: Comparative theoretical and experimental insights into FeNiCoCuMo high-entropy alloy for alkaline oxygen evolution reaction

Víctor M. Jiménez-Arévalo; Pablo Martin; Pedro Zamora; Xiaorong Zhou; Yi Wang; Gino Ramirez; José H. Zagal; Felipe M. Galleguillos Madrid; Maritza Paez

doi:10.1007/s12613-025-3311-7

International Journal of Minerals, Metallurgy, and Materials ›› 2026, Vol. 33 ›› Issue (4) :1279 -1296. DOI: 10.1007/s12613-025-3311-7

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From elemental metals to synergistic electrocatalysis: Comparative theoretical and experimental insights into FeNiCoCuMo high-entropy alloy for alkaline oxygen evolution reaction

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Abstract

Self-supported, hot-pressed FeNiCoCuMo high-entropy alloy (HEA) electrodes were fabricated and characterized by X-ray diffraction (XRD), high-resolution transmission electron microscopy (HR-TEM), and energy dispersive spectroscopy (EDS), confirming a face-centered cubic (FCC) matrix with minor body-centered cubic (BCC) phase (∼1wt%). We map the redox behavior of the individual constituents (Fe, Ni, Co, Cu, and Mo) and compare it with HEA to reveal solid-solution synergy (“cocktail effect”). Electrochemistry (cyclic voltammetry (CV)/linear sweep voltammetry (LSV)/Tafel in 1.0 M KOH) and X-ray photoelectron spectroscopy (XPS) show broadened redox features for HEA and Ni/Co-rich (oxy)hydroxide signatures with MoO_x contributions. Triplicate electrodes (M1–M3) deliver an average overpotential of 370 mV at 10mA·cm⁻² and a Tafel slope of 78 mV·dec⁻¹, outperforming monometallic references and remaining competitive with the literature-reported RuO₂. Chronopotentiometry 100 h evidence stable operation; post-mortem XRD indicates a thin reconstructed surface while the bulk remains FCC-dominated. Density functional theory (DFT) supports broadened electronic states near the Fermi level and enhanced charge transfer. Overall, structure and computation link compositional disorder, surface reconstruction, and oxygen evolution reaction (OER) kinetics in a robust anode for alkaline oxygen evolution.

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high-entropy alloys / mechanical alloying / oxygen evolution reaction / alkaline electrocatalysis

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Víctor M. Jiménez-Arévalo, Pablo Martin, Pedro Zamora, Xiaorong Zhou, Yi Wang, Gino Ramirez, José H. Zagal, Felipe M. Galleguillos Madrid, Maritza Paez. From elemental metals to synergistic electrocatalysis: Comparative theoretical and experimental insights into FeNiCoCuMo high-entropy alloy for alkaline oxygen evolution reaction. International Journal of Minerals, Metallurgy, and Materials, 2026, 33(4): 1279-1296 DOI:10.1007/s12613-025-3311-7

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References

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[1]	Fabbri E, Schmidt TJ. Oxygen evolution reaction: The enigma in water electrolysis. ACS Catal., 2018, 8(10): 9765

[2]	Y. Qin, T.T. Yu, S.H. Deng, et al., RuO₂ electronic structure and lattice strain dual engineering for enhanced acidic oxygen evolution reaction performance, Nat. Commun., 13(2022), No. 1, art. No. 3784.

[3]	V.M. Jiménez-Arévalo, P. Martin, M.F. Sepúlveda, et al., Recent advances in high-entropy alloys for electrocatalysis: From rational design to functional performance, Mater. Des., 258(2025), art. No. 114633.

[4]	H. Ooka, J. Huang, and K.S. Exner, The Sabatier principle in electrocatalysis: Basics, limitations, and extensions, Front. Energy Res., 9(2021), art. No. 654460.

[5]	Hu SL, Li WX. Sabatier principle of metal-support interaction for design of ultrastable metal nanocatalysts. Science, 2021, 374(6573): 1360

[6]	J.M. Tian, Y. Rao, W.H. Shi, et al., Sabatier relations in electrocatalysts based on high-entropy alloys with wide-distributed d-band centers for Li–O₂ batteries, Angew. Chem., 62(2023), No. 44, art. No. e202310894.

[7]	C. Suryanarayana, Mechanical alloying: A novel technique to synthesize advanced materials, Research, 10(2019), art. No. 4219812.

[8]	V.M. Jimenez-Arevalo, P. Martin, E. Pio, et al., Energy transfer by mechanical alloying and electrocatalytic performance of the As-sintered self-supported high-entropy alloy FeNiCoCuMo, Adv. Eng. Mater., 27(2025), No. 6, art. No. 2400807.

[9]	A. Kumar, M. Mucalo, L. Bolzoni, Y. Li, Y. Qu, and F. Yang, Facile synthesis of a NiMnFeCrCu high entropy alloy for electrocatalytic oxygen evolution reactions, Mater. Today Sustain., 22(2023), art. No. 100360.

[10]	Vaidya M, Muralikrishna GM, Murty BS. High-entropy alloys by mechanical alloying: A review. J. Mater. Res., 2019, 34(5): 664

[11]	Varalakshmi S, Kamaraj M, Murty BS. Processing and properties of nanocrystalline CuNiCoZnAlTi high entropy alloys by mechanical alloying. Mater. Sci. Eng. A, 2010, 527(4–5): 1027

[12]	Chen ZB, Huang K, Zhang BW, et al. . Corrosion engineering on AlCoCrFeNi high-entropy alloys toward highly efficient electrocatalysts for the oxygen evolution of alkaline seawater. Int. J. Miner. Metall. Mater., 2023, 30(10): 1922

[13]	J.X. Li, K. Yamanaka, J.H. Hu, and A. Chiba, Suzuki segregation behavior and mechanism in a Co–Cr–Fe–Ni–Mo high-entropy alloy, Mater. TodayPhys., 45(2024), art. No. 101468.

[14]	Sabir AS, Pervaiz E, Khosa R, Sohail U. An inclusive review and perspective on Cu-based materials for electrochemical water splitting. RSC Adv., 2023, 13(8): 4963

[15]	Z.Y. He, J. Zhang, Z.H. Gong, et al., Activating lattice oxygen in NiFe-based (oxy)hydroxide for water electrolysis, Nat. Commun., 13(2022), No. 1, art. No. 2191.

[16]	Lutterotti L, Bortolotti M, Ischia G, Lonardelli I, Wenk HR. Rietveld texture analysis from diffraction images. Z. Kristallogr. Suppl., 2007, 2007(suppl_26): 125

[17]	de Keijser TH, Langford JI, Mittemeijer EJ, Vogels ABP. Use of the Voigt function in a single-line method for the analysis of X-ray diffraction line broadening. J. Appl. Crystallogr., 1982, 15(3): 308

[18]	Delhez R, de Keijser TH, Langford JI, Louër D, Mittemeijer EJ, Sonneveld EJYoung RA. Crystal imperfection broadening and peak shape in the Rietveld method. The Rietveld Method, 1993, 132

[19]	Popa NC. The (hkl) dependence of diffraction-line broadening caused by strain and size for all Laue groups in rietveld refinement. J. Appl. Crystallogr., 1998, 31(2): 176

[20]	X.H. Xie, L. Du, L.T. Yan, et al., Oxygen evolution reaction in alkaline environment: Material challenges and solutions, Adv. Funct. Mater., 32(2022), No. 21, art. No. 2110036.

[21]	Connor P, Schuch J, Kaiser B, Jaegermann W. The determination of electrochemical active surface area and specific capacity revisited for the system MnO_x as an oxygen evolution catalyst. Z. Phys. Chem., 2020, 234(5): 979

[22]	Martin P, Salvo C, Pio E, et al. . A study on the phase formation and magnetic properties of FeNiCoCuM (M = Mo, Nb) high-entropy alloys processed through powder metallurgy. Metall. Mater. Trans. A, 2021, 52(3): 1044

[23]	Lang P, Wojcik T, Povoden-Karadeniz E, Falahati A, Kozeschnik E. Thermo-kinetic prediction of metastable and stable phase precipitation in Al–Zn–Mg series aluminium alloys during non-isothermal DSC analysis. J. Alloys Compd., 2014, 609: 129

[24]	A. Kumar, M. Mucalo, L. Bolzoni, Y.M. Li, F.T. Kong, and F. Yang, Fabrication, microstructure, mechanical, and electrochemical properties of NiMnFeCu high entropy alloy from elemental powders, Metals, 12(2022), No. 1, art. No. 167.

[25]	Martin P, Muñoz JA, Ferrari B, Sanchez-Herencia AJ, Aguilar C, Cabrera JM. Microstructure and constitutive modeling of an ultrafine-grained refractory high-entropy alloy fabricated by powder metallurgy. J. Mater. Res. Technol., 2024, 30: 7910

[26]	P. Martin, C.E. Madrid-Cortes, C. Cáceres, N.L. Araya, C. Aguilar, and J.M. Cabrera, HEAPS: A user-friendly tool for the design and exploration of high-entropy alloys based on semi-empirical parameters, Comput. Phys. Commun., 278(2022), art. No. 108398.

[27]	Li P, Wan XH, Su JH, et al. . A single-phase FeCoNiMnMo high-entropy alloy oxygen evolution anode working in alkaline solution for over 1000 h. ACS Catal., 2022, 12(19): 11667

[28]	Shang XL, Wang ZJ, Wu QF, Wang JC, Li JJ, Yu JK. Effect of Mo addition on corrosion behavior of high-entropy alloys CoCrFeNiMo_x in aqueous environments. Acta Metall. Sin. Engl. Lett., 2019, 32(1): 41

[29]	Luan CL, Escalera-López D, Hagemann U, et al. . Revealing dynamic surface and subsurface reconstruction of high-entropy alloy electrocatalysts during the oxygen evolution reaction at the atomic scale. ACS Catal., 2024, 14(17): 12704

[30]	M. Han, C.H. Wang, J. Zhong, et al., Promoted self-construction of β-NiOOH in amorphous high entropy electrocatalysts for the oxygen evolution reaction, Appl. Catal. B: Environ., 301(2022), art. No. 120764.

[31]	S.M. Chen, L.T. Ma, Z.D. Huang, G.J. Liang, and C.Y. Zhi, In situ/operando analysis of surface reconstruction of transition metal-based oxygen evolution electrocatalysts, Cell Rep. Phys. Sci., 3(2022), No. 1, art. No. 100729.

[32]	Wang KX, Xu YF, Daneshvariesfahlan V, et al. . Insight into the structural reconstruction of alkaline water oxidation electrocatalysts. Nanoscale, 2025, 17(11): 6287

[33]	T. Cao, J. Cheng, Y. Xiang, et al., Activating surface oxygen in Ce/Mo-doped Ni oxyhydroxide for synergistically enhancing furfural oxidation and hydrogen evolution at ampere-level current densities, Angew. Chem. Int. Ed., 64(2025), No. 28, art. No. e202506017.

[34]	Wang W, Wang WQ, Cheng J, Lu X, Lu YZ. Biomimetic hierarchical porous high entropy alloy for significantly enhancing overall seawater splitting. Chem. Commun., 2024, 60(63): 8276

[35]	Wu QY, Alkemper A, Lauterbach S, Hofmann JP, Einert M. Fabrication of nanocrystalline high-entropy oxide CoNi-FeCrMnO, thin film electrodes by dip-coating for oxygen evolution electrocatalysis. Energy Adv., 2024, 3(4): 765

[36]	Shen TH, Spillane L, Peng JY, Shao-Horn Y, Tileli V. Switchable wetting of oxygen-evolving oxide catalysts. Nat. Catal., 2022, 5(1): 30

[37]	C.H. Zhang, Z. Xu, N.N. Han, et al., Superaerophilic/superaerophobic cooperative electrode for efficient hydrogen evolution reaction via enhanced mass transfer, Sci. Adv., 9(2023), No. 3, art. No. eadd6978.

[38]	Bhardwaj K, Parvis F, Wang YF, Blanchard GJ, Swain GM. Effect of surface oxygen on the wettability and electrochemical properties of boron-doped nanocrystalline diamond electrodes in room-temperature ionic liquids. Langmuir, 2020, 36(21): 5717

[39]	McKone JR, Sadtler BF, Werlang CA, Lewis NS, Gray HB. Ni–Mo nanopowders for efficient electrochemical hydrogen evolution. ACS Catal., 2013, 3(2): 166

[40]	Huo XR, Zhang YW, Yu HS, et al. . Bulk CoCrFeNiAlMo high entropy alloy as high-efficient electrocatalyst in alkaline environment. Int. J. Hydrogen Energy, 2024, 87: 505

[41]	P.I. Odetola, B.J. Babalola, A.E. Afolabi, et al, Exploring high entropy alloys: A review on thermodynamic design and computational modeling strategies for advanced materials applications, Heliyon, 10(2024), No. 22, art. No. e39660.

[42]	Gong M, Li YG, Wang HL, et al. . An advanced Ni–Fe layered double hydroxide electrocatalyst for water oxidation. J. Am. Chem. Soc., 2013, 135(23): 8452

[43]	L.J. Zhang, W.W. Cai, and N.Z. Bao, Top-level design strategy to construct an advanced high-entropy Co–Cu–Fe–Mo (oxy)hydroxide electrocatalyst for the oxygen evolution reaction, Adv. Mater., 33(2021), No. 22, art. No. 2100745.

[44]	Thompson WT, Kaye MH, Bale CW, Pelton ADWinston Revie R. Pourbaix diagrams for multielement systems. Uhlig’s Corrosion Handbook, 2011, 103 Vol.3

[45]	C. Wei, R.R. Rao, J.Y. Peng, et al., Recommended practices and benchmark activity for hydrogen and oxygen electrocatalysis in water splitting and fuel cells, Adv. Mater., 31(2019), No. 31, art. No. 1806296.

[46]	H.M. An, W. Park, H.J. Shin, and D.Y. Chung, Recommended practice for measurement and evaluation of oxygen evolution reaction electrocatalysis, EcoMat, 6(2024), No. 10, art. No. e12486.

[47]	Sharma L, Katiyar NK, Parui A, et al. . Low-cost high entropy alloy (HEA) for high-efficiency oxygen evolution reaction (OER). Nano Res., 2022, 15(6): 4799

[48]	He YZ, Wu JZ, Hu FY, et al. . Self-supporting FeCoNi-CuTiGa high-entropy alloy electrodes for alkaline hydrogen and oxygen evolution reactions: Experimental and theoretical insights. ACS Appl. Energy Mater., 2024, 7(20): 9121

[49]	X. Wang, R.K.M. Raghupathy, C.J. Querebillo, et al., Interfacial covalent bonds regulated electron-deficient 2D black phosphorus for electrocatalytic oxygen reactions, Adv. Mater., 33(2021), No. 20, art. No. 2008752.

[50]	Cao BX, Wang C, Yang T, Liu CT. Cocktail effects in understanding the stability and properties of face-centered-cubic high-entropy alloys at ambient and cryogenic temperatures. Scripta Mater., 2020, 187: 250

[51]	Chen JX, Ji YX. Locating the cocktail and scaling-relation breaking effects of high-entropy alloy catalysts on the electrocatalytic volcano plot. Chin. J. Catal., 2022, 43(11): 2889

[52]	S. Rajendrachari, N. Basavegowda, R. Vinaykumar, D. Narsimhachary, P. Somu, and M.J. Lee, Electrocatalytic determination of methyl orange dye using mechanically alloyed novel metallic glass modified carbon paste electrode by cyclic voltammetry, Inorg. Chem. Commun., 155(2023), art. No. 111010.

[53]	Madan C, Jha SR, Katiyar NK, et al. . Understanding the evolution of catalytically active multi-metal sites in a bifunctional high-entropy alloy electrocatalyst for zinc-air battery application. Energy Adv., 2023, 2(12): 2055

[54]	Grosvenor AP, Biesinger MC, Smart RSC, McIntyre NS. New interpretations of XPS spectra of nickel metal and oxides. Surf. Sci., 2006, 600(9): 1771

[55]	Laïk B, Richet M, Emery N, et al. . XPS investigation of Co–Ni oxidized compounds surface using peak-on-satellite ratio. application to Co₂₀Ni₈₀ passive layer structure and composition. ACS Omega, 2024, 9(39): 40707

[56]	Dai J, Feng H, Li HB, et al. . Insights into the mechanism of Mo protecting CoCrFeNi HEA from pitting corrosion: A quantitative modelling study on passivation and repassivation processes. J. Mater. Sci. Technol., 2024, 182: 152

[57]	Biesinger MC. Advanced analysis of copper X-ray photoelectron spectra. Surf. Interface Anal., 2017, 49(13): 1325

[58]	Cancellieri C, Lorenzin G, Lyanage M, Turlo V, Watts JF, Jeurgens LPH. Chemical and electronic structure of buried W/Cu, W/Cr, and W/Mo interfaces by in situ XPS/HAX-PES auger parameter analysis. Surf. Interface Anal., 2025, 57(5): 357

[59]	L.T. Wang, S. Zanna, D. Mercier, V. Maurice, and P. Marcus, Early-stage surface oxidation of the equiatomic CoCrFeMnNi high entropy alloy studied in situ by XPS, Corros. Sci., 220(2023), art. No. 111310.

[60]	L.T. Wang, D. Mercier, S. Zanna, et al., Study of the surface oxides and corrosion behaviour of an equiatomic CoCrFeMnNi high entropy alloy by XPS and ToF-SIMS, Corros. Sci., 167(2020), art. No. 108507.

[61]	Mazur N, Huinink H, Fischer H, Adan O. Impact of atmospheric CO₂ on thermochemical heat storage capabilities of K₂CO₃. Energy Fuels, 2022, 36(23): 14464

[62]	Jiang SS, Zhu L, Yang ZZ, Wang YG. Self-supported hierarchical porous FeNiCo-based amorphous alloys as high-efficiency bifunctional electrocatalysts toward overall water splitting. Int. J. Hydrogen Energy, 2021, 46(74): 36731

[63]	A. Karmakar and S. Kundu, A concise perspective on the effect of interpreting the double layer capacitance data over the intrinsic evaluation parameters in oxygen evolution reaction, Mater. Today Energy, 33(2023), art. No. 101259.

[64]	Kayode GO, Montemore MM. Factors controlling oxophilicity and carbophilicity of transition metals and main group metals. J. Mater. Chem. A, 2021, 9(39): 22325