Dual-ligand surface engineering of Ni-based nanostructures for efficient urea electrooxidation via Ni3+ activation and charge-transfer modulation
Wang Yifei, Li Jiayin, Luo An, Jin Yanxian, Xu Wei, Chen Dan, Yu Hua, Worathat Thitikornpong, Yu Binbin

TL;DR
This paper introduces a new method to improve nickel-based catalysts for urea oxidation, enhancing hydrogen production and wastewater treatment.
Contribution
A dual-ligand surface engineering strategy is proposed to optimize nickel-based catalysts for urea electrooxidation.
Findings
The modified catalyst shows a low onset potential of 0.49 V vs. SCE for urea oxidation.
The material exhibits a minimal Tafel slope of 20.98 mV dec−1 and excellent electrochemical durability.
Glutaric acid-induced structural disorder enhances interfacial charge transfer.
Abstract
Nickel-based metallic nanomaterials represent highly promising electrocatalysts for the urea oxidation reaction (UOR), enabling the simultaneous benefits of efficient hydrogen production and wastewater treatment. However, their catalytic performance is constrained by slow interfacial charge transfer and insufficient exposure of active Ni3+ sites. Herein, we propose a dual-ligand surface modification strategy employing glutaric acid (Ga) and ferrocenecarboxylic acid (Fc) as co-modifiers alongside phthalic acid as the primary linker, simultaneously optimising the geometric structure and electronic state of the nickel-based catalyst. The optimally modified nickel-based catalyst exhibits a rich array of surface defect morphologies, and XPS analysis confirms that under this modification scheme, the material's specific surface area increases moderately (71.3 m2 g−1), with a marked enhancement…
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Taxonomy
TopicsElectrocatalysts for Energy Conversion · Ammonia Synthesis and Nitrogen Reduction · Advanced oxidation water treatment
