Surface evolution of a Pt–Pd–Au electrocatalyst for stable oxygen reduction

电催化剂 催化作用 材料科学 纳米材料基催化剂 扫描透射电子显微镜 纳米孔 合金 化学工程 透射电子显微镜 金属 化学 纳米技术 电化学 电极 冶金 物理化学 工程类 生物化学
作者
Jian Li,Huiming Yin,Xi‐Bo Li,Eiji Okunishi,Yongli Shen,Jia He,Zhen‐Kun Tang,Wenxin Wang,Emrah Yücelen,Chao Li,Yue Gong,Lin Gu,Shu Miao,Yuandong Niu,Jun Luo,Yi Ding
出处
期刊:Nature Energy [Nature Portfolio]
卷期号:2 (8) 被引量:385
标识
DOI:10.1038/nenergy.2017.111
摘要

Core–shell nanocatalysts have demonstrated potential as highly active low-Pt fuel cell cathodes for the oxygen reduction reaction (ORR); however, challenges remain in optimizing their surface and interfacial structures, which often exhibit undesirable structural degradation and poor durability. Here, we construct an unsupported nanoporous catalyst with a Pt–Pd shell of sub-nanometre thickness on Au, which demonstrates an initial ORR activity of 1.140 A mgPt−1 at 0.9 V. The activity increases to 1.471 A mgPt−1 after 30,000 potential cycles and is stable over a further 70,000 cycles. Using aberration-corrected scanning transmission electron microscopy and atomically resolved elemental mapping, the origin of the activity change is revealed to be an atomic-scale evolution of the shell from an initial Pt–Pd alloy into a bilayer structure with a Pt-rich trimetallic surface, and finally into a uniform and stable Pt–Pd–Au alloy. This Pt–Pd–Au alloy possesses a suitable configuration for ORR, giving a relatively low free energy change for the final water formation from adsorbed OH intermediate during the reaction. Metal alloys possessing core–shell structures have potential as low-Pt catalysts for the oxygen reduction reaction in fuel cells, but can suffer from poor stability. Using high-resolution microscopy, Li et al. find that a Pt–Pd–Au catalyst undergoes surface atomic rearrangement and becomes more active on electrochemical cycling.
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