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Enhanced Alkaline Water Electrolysis by the Rational Decoration of RuO x with the In Situ-Grown CoFe NanolayerEnhanced Alkaline Water Electrolysis by the Rational Decoration of RuOx with the In Situ-Grown CoFe Nanolayer

Other Titles
Enhanced Alkaline Water Electrolysis by the Rational Decoration of RuOx with the In Situ-Grown CoFe Nanolayer
Authors
Kim, SangwooLee, JeongahKim, Yong BeomOh, DonghwanKim, Jun KyuKoo, BonjaeKim, HyunseungJung, Gi hongKim, MinjoongDoo, GisuSeo, JongsuLim, Tae JinKim, KyeounghakHan, Jeong WooJung, Woochul
Issue Date
Mar-2025
Publisher
American Chemical Society
Keywords
water splitting; perovskite oxide; ex-solution; ruthenium; encapsulation
Citation
ACS Nano, v.19, no.10, pp 10026 - 10037
Pages
12
Indexed
SCIE
SCOPUS
Journal Title
ACS Nano
Volume
19
Number
10
Start Page
10026
End Page
10037
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/206822
DOI
10.1021/acsnano.4c16691
ISSN
1936-0851
1936-086X
Abstract
Rational engineering of the surfaces of heterogeneous catalysts (especially the surfaces of supported metals) can endow intriguing catalytic functionalities for electrochemical reactions. However, it often requires complicated steps, and even if it does not, breaking the trade-off between activity and stability is quite challenging. Herein, we present a strategy for reconstructing supported catalysts via in situ growth of metallic nanolayers from the perovskite oxide support. When Ru-coated LaFe0.9Co0.1O3 is thermally reduced, the CoFe nanoalloy spontaneously migrates onto the Ru and greatly increases the physicochemical stability of Ru in alkaline water electrolysis. Benefiting from an 81% reduction in Ru dissolution after decoration, it operates for over 200 h without noticeable degradation. Furthermore, the underlying Ru modifies the electronic structure and surface adsorption properties of the CoFe overlayer toward reaction intermediates, synergistically catalyzing both the oxygen evolution reaction and the hydrogen evolution reaction. Specifically, the mass activity of the oxygen evolution reaction is 64.1 times greater than that of commercial RuO2. Our work highlights a way to protect inherently unstable Ru from dissolution while allowing it to influence surface kinetics from the subsurface sites in heterogeneous catalysts.
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