Ruthenium nanoparticles decorated with surface hydroxyl and borate species boost overall seawater splitting via increased hydrophilicity

The use of seawater electrolysis for hydrogen production faces several serious challenges, including the rapid deactivation of electrocatalysts through chloride anion (Cl − ) induced corrosion. We have demonstrated that Ru nanoparticles possessing an abundance of surface hydroxyl groups along with b...

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Bibliographic Details
Published in:Energy & environmental science 2024, Vol.17 (11), p.3888-3897
Main Authors: Shen, Le-Wei, Wang, Yong, Shen, Ling, Chen, Jiang-Bo, Liu, Yu, Hu, Ming-Xia, Zhao, Wen-Ying, Xiong, Kang-Yi, Wu, Si-Ming, Lu, Yi, Ying, Jie, Titirici, Maria Magdalena, Janiak, Christoph, Tian, Ge, Yang, Xiao-Yu
Format: Article
Language:English
Subjects:
Anion exchanging
Corrosion
Corrosion resistance
Electrocatalysts
Electrolysis
Hydrogen production
Hydroxyl groups
Nanoparticles
Ruthenium
Seawater
Splitting
Stability
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Summary:The use of seawater electrolysis for hydrogen production faces several serious challenges, including the rapid deactivation of electrocatalysts through chloride anion (Cl − ) induced corrosion. We have demonstrated that Ru nanoparticles possessing an abundance of surface hydroxyl groups along with borate species (Ru–BO x –OH) exhibit high activity and stability as electrocatalysts for seawater splitting. The optimal electrocatalyst (Ru–BO x –OH-300) uncovered in this study displays an extremely high catalytic performance for both the hydrogen (HER) and oxygen (OER) evolution reactions in alkaline seawater (HER, 22 mV and OER, 235 mV at 10 mA cm −2 ), as well as a low cell voltage (1.47 V) and ultra-long-term stability (1000 hours at 10, 50 and 100 mA cm −2 ) for overall seawater splitting. Furthermore, the Ru–BO x –OH-300-based anion-exchange membrane seawater electrolyzer requires only 1.73 or 1.95 V to reach a current density of 500 or 1000 mA cm −2 , respectively, and exhibits excellent stability for 400 hours without obvious decay. The results of the experiments and theoretical calculations reveal that the high water affinity of Ru–BO x –OH-300 caused by the presence of hydroxyl and borate species on the metallic Ru surface is responsible for the superb electrocatalytic performance and that the borate species are the source of Cl − corrosion resistance. These findings provide new perspectives for the design of high-performance electrocatalysts for seawater splitting.
ISSN:1754-5692
1754-5706
DOI:10.1039/D4EE00950A