Stability of Ni–Fe‐Layered Double Hydroxide Under Long‐Term Operation in AEM Water Electrolysis

Anion exchange membrane water electrolysis (AEMWE) is an attractive method for green hydrogen production. It allows the use of non‐platinum group metal catalysts and can achieve performance comparable to proton exchange membrane water electrolyzers due to recent technological advances. While current...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2024-06, Vol.20 (26), p.e2311047-n/a
Main Authors: Galkina, Irina, Faid, Alaa Y., Jiang, Wulyu, Scheepers, Fabian, Borowski, Patrick, Sunde, Svein, Shviro, Meital, Lehnert, Werner, Mechler, Anna K.
Format: Article
Language:English
Subjects:
anion exchange membrane water electrolysis
Anion exchanging
catalyst layers
Catalysts
Durability
electrode degradation studies
Electrodes
Electrolysis
Electrolytic cells
electrolyzer durability
Green hydrogen
Hydrogen production
Hydroxides
Intermetallic compounds
Iron
Iron compounds
Leaching
Membranes
Nickel base alloys
Nickel compounds
NiFe LDH catalysts
Performance degradation
Platinum metals
post‐mortem analysis
Stability tests
Tracking
water electrolysis
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Summary:Anion exchange membrane water electrolysis (AEMWE) is an attractive method for green hydrogen production. It allows the use of non‐platinum group metal catalysts and can achieve performance comparable to proton exchange membrane water electrolyzers due to recent technological advances. While current systems already show high performances with available materials, research gaps remain in understanding electrode durability and degradation behavior. In this study, the performance and degradation tracking of a Ni3Fe–LDH‐based single‐cell is implemented and investigated through the correlation of electrochemical data using chemical and physical characterization methods. A performance stability of 1000 h, with a degradation rate of 84 µV h−1 at 1 A cm−2 is achieved, presenting the Ni3Fe−LDH‐based cell as a stable and cost‐attractive AEMWE system. The results show that the conductivity of the formed Ni‐Fe‐phase is one key to obtaining high electrolyzer performance and that, despite Fe leaching, change in anion‐conducting binder compound, and morphological changes inside the catalyst bulk, the Ni3Fe−LDH‐based single‐cells demonstrate high performance and durability. The work reveals the importance of longer stability tests and presents a holistic approach of electrochemical tracking and post‐mortem analysis that offers a guideline for investigating electrode degradation behavior over extended measurement periods. Transitioning industrial processes toward renewable energy is vital for decarbonization. Green hydrogen, generated via anion exchange membrane water electrolysis (AEMWE) offers cost‐effective, efficient hydrogen production. While recent research has improved AEMWE components, long‐term durability and comprehensive electrode studies are lacking. This study investigates a Ni3Fe‐LDH‐based single‐cell's 1000 h operation, tracking anode degradation, and establishing correlations with overall cell stability.
ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202311047