Authors: Wenzhe Tu, Wenjia Luo, Changli Chen, Kai Chen, Enbo Zhu, Zipeng Zhao, Zelin Wang, Tao Hu, Huachao Zai, Xiaoxing Ke, Manling Sui, Pengwan Chen, Qingshan Zhang, Qi Chen, Yujing Li, Yu Huang
Published: 2019-12-04
Source: Full article
AbstractPt‐based alloy nanocrystals have shown great success in oxygen reduction electrocatalysis owing to their unique surface and electronic structures. However, they suffer from severe stability issues due to the dissolution of non‐noble metal elements, leading to the “trade‐off” between activity and stability. In this work, targeting the stability issue of a PtxCuy‐based alloy, Pt2CuW0.25 ternary alloy nanoparticles are synthesized by thermal reduction strategy based on wet‐chemical method using W(CO)6 as a reductant. Apart from the competitive activity, the obtained Pt2CuW0.25/C shows remarkable stability, whereby the area specific activity and mass activity maintain 89.5% and 95.9% of the initial values, respectively, after 30 000 cycles of accelerated polarization between 0.6 and 1.1 V (vs reversible hydrogen electrode). By using vacancy formation energy of surface Pt as the descriptor, it is found that the enhanced stability of Pt2CuW0.25/C originates mainly from the stronger bonding between W and Pt/Cu atoms, acting as an “adhesive” to stabilize the atoms from dissolution, which is further verified by chemical stability experiments. This work demonstrates a rational design strategy for ternary alloy nano‐electrocatalyst that has high thermodynamic stability while maintaining high activity by employing high‐melting‐point metal.