Exceptional electrocatalytic oxygen evolution via tunable charge transfer interactions in La0.5Sr1.5Ni1−xFexO4±δ Ruddlesden-Popper oxides

The electrolysis of water is of global importance to store renewable energy and the methodical design of next-generation oxygen evolution catalysts requires a greater understanding of the structural and electronic contributions that give rise to increased activities. Herein, we report a series of Ru...

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Published in:Nature communications 2018-08, Vol.9 (1), p.3150-3150, Article 3150
Main Authors: Forslund, Robin P., Hardin, William G., Rong, Xi, Abakumov, Artem M., Filimonov, Dmitry, Alexander, Caleb T., Mefford, J. Tyler, Iyer, Hrishikesh, Kolpak, Alexie M., Johnston, Keith P., Stevenson, Keith J.
Format: Article
Language:English
Subjects:
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ENERGY STORAGE
Humanities and Social Sciences
multidisciplinary
Other Topics
Science
Science & Technology
Science (multidisciplinary)
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Summary:The electrolysis of water is of global importance to store renewable energy and the methodical design of next-generation oxygen evolution catalysts requires a greater understanding of the structural and electronic contributions that give rise to increased activities. Herein, we report a series of Ruddlesden–Popper La 0.5 Sr 1.5 Ni 1− x Fe x O 4± δ oxides that promote charge transfer via cross-gap hybridization to enhance electrocatalytic water splitting. Using selective substitution of lanthanum with strontium and nickel with iron to tune the extent to which transition metal and oxygen valence bands hybridize, we demonstrate remarkable catalytic activity of 10 mA cm −2 at a 360 mV overpotential and mass activity of 1930 mA mg −1 ox at 1.63 V via a mechanism that utilizes lattice oxygen. This work demonstrates that Ruddlesden–Popper materials can be utilized as active catalysts for oxygen evolution through rational design of structural and electronic configurations that are unattainable in many other crystalline metal oxide phases. Water electrolysis provides a potential means to large-scale renewable fuel generation, although sluggish oxygen evolution kinetics challenges progress. Here, authors report on Ruddlesden–Popper oxides as active oxygen evolution electrocatalysts that provide impetus for overcoming kinetic barriers.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-018-05600-y