| Literature DB >> 28990777 |
Kun Sun1, Tao Cheng2, Lina Wu3, Yongfeng Hu4, Jigang Zhou4, Aimee Maclennan4, Zhaohua Jiang1, Yunzhi Gao1, William A Goddard2, Zhijiang Wang1.
Abstract
Wide application of carbon dioxide (CO2) electrochemical energy storage requires catalysts with high mass activity. Alloy catalysts can achieve superior performance to single metals while reducing the cost by finely tuning the composition and morphology. We used in silico quantum mechanics rapid screening to identify Au-Fe as a candidate improving CO2 reduction and then synthesized and tested it experimentally. The synthesized Au-Fe alloy catalyst evolves quickly into a stable Au-Fe core-shell nanoparticle (AuFe-CSNP) after leaching out surface Fe. This AuFe-CSNP exhibits exclusive CO selectivity, long-term stability, nearly a 100-fold increase in mass activity toward CO2 reduction compared with Au NP, and 0.2 V lower in overpotential. Calculations show that surface defects due to Fe leaching contribute significantly to decrease the overpotential.Entities:
Year: 2017 PMID: 28990777 DOI: 10.1021/jacs.7b09251
Source DB: PubMed Journal: J Am Chem Soc ISSN: 0002-7863 Impact factor: 15.419