Industrial-scale efficient alkaline water electrolysis achieved with sputtered NiFeV-oxide thin film electrodes for green hydrogen production

We propose a magnetron sputtering technique to enhance HER and OER performance with a bifunctional vanadium-substituted NiFe-based catalyst electrode formed into a NiFeV-oxide thin film. The sputtering approach generates oxygen vacancies by creating nonstoichiometric oxidation phases, i.e. , Fe 3 O...

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Bibliographic Details
Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2023-12, Vol.12 (1), p.46-474
Main Authors: Ha, Quoc-Nam, Yeh, Chen-Hao, Gultom, Noto Susanto, Kuo, Dong-Hau
Format: Article
Language:English
Subjects:
Alkaline water
Anodizing
Catalysts
Electrocatalysts
Electrodes
Electrolysis
Feasibility studies
Green hydrogen
Hydrogen production
Intermediates
Intermetallic compounds
Iron compounds
Iron oxides
Leaching
Magnetron sputtering
Nickel compounds
Oxidation
Oxygen
Phase transitions
Raman spectroscopy
Synergistic effect
Thin films
Vanadium
Water splitting
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Summary:We propose a magnetron sputtering technique to enhance HER and OER performance with a bifunctional vanadium-substituted NiFe-based catalyst electrode formed into a NiFeV-oxide thin film. The sputtering approach generates oxygen vacancies by creating nonstoichiometric oxidation phases, i.e. , Fe 3 O 4− x and VO 2− y . Operando Raman spectroscopy reveals a synergistic effect between active metal sites and oxygen vacancies to promote the formation of a reconstructed active layer, i.e. , NiFe(oxy)hydroxyl, during anodic oxidation. This phase transition optimizes the adsorption energy of water intermediates to accelerate the water splitting. Moreover, the leaching of vanadium also plays a vital role in the activation and surface restructuring processes of the NiFeV-oxide pre-catalyst during OER electrocatalysis. Feasibility studies for an NFV-0.7(−)|NFV-0.7(+) stack-cell electrolyzer indicate that it delivers a high current density of 1000 mA cm −2 at low cell potentials of 2.00 V (without cell heating) and 1.84 V (at 60 °C) and exhibits excellent stability at 1000 mA cm −2 over 100 h. Our work offers a new paradigm for designing efficient bifunctional electrocatalysts, holding great promise for industrial-scale water splitting. To mitigate electrocatalyst peel-off under high current conditions, sputtering technology is employed to craft bifunctional electrocatalyst films, specifically ternary NiFeV-oxide films with varied V compositions for enabling comprehensive alkaline water splitting in industrial applications.
ISSN:2050-7488
2050-7496
DOI:10.1039/d3ta05699f