Assembling molybdenum-doped platinum clusters into a coral-like nanostructure for highly enhanced oxygen reduction

IF 42.9 Q1 ELECTROCHEMISTRY
Linwei Zheng , Mang Niu , Tiantian Zeng , Xiaohang Ge , Yanrui Wang , Chun Xian Guo , Weiyong Yuan , Dapeng Cao , Lian Ying Zhang , Chang Ming Li
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Abstract

Regulating the electronic and geometric structures of electrocatalysts is an effective strategy to boost their catalytic properties. Herein, a coral-like nanostructure is assembled with Mo-doped Pt clusters to form a highly active catalyst toward the oxygen reduction reaction (ORR). The advantages of a Mo-doped porous skeleton, grain boundaries, and MoOx species on the Pt cluster surfaces synergistically boost the electrocatalytic performance. This unique architecture delivers 3.5- and 2.8-fold higher mass and specific activities, respectively, than commercial Pt/C. Density functional theory calculations reveal that the Mo-doped Pt clusters have an optimized Pt–O bond length of 2.110 ​Å, which weakens the adsorption energy of the intermediate O∗ to yield great ORR activity. Moreover, the catalyst shows a decay in the half-wave potential of only 8 ​mV after 10,000 cycles of accelerated durability testing. The high stability arises from the increased dissociation energy of Pt atoms and the stable architecture of the coral-like structure of clusters.

Abstract Image

Abstract Image

将掺钼铂团簇组装成珊瑚状纳米结构,以实现高度增强的氧还原能力
调节电催化剂的电子和几何结构是提高其催化性能的有效策略。在这里,珊瑚状纳米结构与掺杂钼的铂团簇组装在一起,形成了一种高活性的氧还原反应(ORR)催化剂。掺杂钼的多孔骨架、晶界和铂团簇表面的氧化钼物种等优势协同提高了电催化性能。与商用 Pt/C 相比,这种独特的结构可使质量活性和比活性分别提高 3.5 倍和 2.8 倍。密度泛函理论计算显示,掺杂钼的铂团簇具有 2.110 Å 的优化铂-铂键长,这减弱了中间 O∗ 的吸附能,从而产生了极高的 ORR 活性。此外,在经过 10,000 次加速耐久性测试后,催化剂的半波电位衰减仅为 8 mV。高稳定性源于铂原子解离能的增加和珊瑚状团簇结构的稳定架构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
33.70
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