| Literature DB >> 32541950 |
Zhi Li1, Yuanjun Chen1, Shufang Ji1, Yan Tang1, Wenxing Chen1, Ang Li2, Jie Zhao3, Yu Xiong1, Yuen Wu4, Yue Gong5, Tao Yao6, Wei Liu6, Lirong Zheng7, Juncai Dong7, Yu Wang8, Zhongbin Zhuang9, Wei Xing10,11, Chun-Ting He12, Chao Peng13,14, Weng-Chon Cheong1, Qiheng Li1, Maolin Zhang1, Zheng Chen1, Ninghua Fu1, Xin Gao1, Wei Zhu1, Jiawei Wan1, Jian Zhang1, Lin Gu5, Shiqiang Wei6, Peijun Hu13,14, Jun Luo15, Jun Li1, Chen Chen1, Qing Peng1, Xiangfeng Duan16,17, Yu Huang17,18, Xiao-Ming Chen12, Dingsheng Wang19, Yadong Li20,21.
Abstract
Single-atom catalysts not only maximize metal atom efficiency, they also display properties that are considerably different to their more conventional nanoparticle equivalents, making them a promising family of materials to investigate. Herein we developed a general host-guest strategy to fabricate various metal single-atom catalysts on nitrogen-doped carbon (M1/CN, M = Pt, Ir, Pd, Ru, Mo, Ga, Cu, Ni, Mn). The iridium variant Ir1/CN electrocatalyses the formic acid oxidation reaction with a mass activity of 12.9 [Formula: see text] whereas an Ir/C nanoparticle catalyst is almost inert (~4.8 × 10-3 [Formula: see text]). The activity of Ir1/CN is also 16 and 19 times greater than those of Pd/C and Pt/C, respectively. Furthermore, Ir1/CN displays high tolerance to CO poisoning. First-principle density functional theory reveals that the properties of Ir1/CN stem from the spatial isolation of iridium sites and from the modified electronic structure of iridium with respect to a conventional nanoparticle catalyst.Entities:
Year: 2020 PMID: 32541950 DOI: 10.1038/s41557-020-0473-9
Source DB: PubMed Journal: Nat Chem ISSN: 1755-4330 Impact factor: 24.427