材料科学
电催化剂
催化作用
纳米颗粒
原电池
纳米结构
甲醇
合金
化学工程
纳米技术
氧还原反应
表面工程
曲面(拓扑)
原子单位
钯
碳纤维
工作(物理)
氧气
扩散
表面改性
原子扩散
氧原子
Atom(片上系统)
金属间化合物
作者
Mengyuan Ma,Qing Zeng,Bao Zhang,H Liu,Shaonan Tian,Dong Chen,Jun Yang
摘要
ABSTRACT Surface atomic steps serve as highly active sites for electrocatalysis, yet their controllable construction remains challenging. Herein, we report a facile strategy combining galvanic replacement and Au‐catalyzed reduction to fabricate AuCu@Pd core‐shell nanoparticles with dense surface Pd atomic steps on carbon substrate. Binary AuCu nanoalloy seeds were prepared via a Joule‐heating‐driven solid‐state diffusion method. Subsequently, Pd atoms substitute Cu atoms on the surface of AuCu alloy seeds, maintaining a flat surface morphology; next, Pd atoms selectively deposit on Au sites, forming atomic steps together with the Pd atoms that substituted Cu atoms in the last step. The optimized Au 10 Cu 5 @Pd 4 /C catalyst exhibits exceptional oxygen reduction reaction (ORR) performance in alkaline media, with a half‐wave potential of 0.92 V versus RHE, a specific activity of 1.29 mA cm −2 and a mass activity of 2.86 A mg Pd −1 , significantly outperforming commercial Pd/C. Control experiments verify that surface Pd atomic steps dominate the enhanced ORR activity. This strategy is further extended to synthesize AuCu@Pt nanoparticles with surface Pt steps, which show superior methanol oxidation activity. This work provides a universal approach to engineering surface atomic steps for high‐performance electrocatalysts.
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