Atomically dispersed metal–nitrogen–carbon catalysts for fuel cells: advances in catalyst design, electrode performance, and durability improvement

Sites and their local structures are crucial for enhancing intrinsic activity. Increasing the site density relies on the innovative strategies of restricting the migration and agglomeration of single metal sites into metallic clusters. Relevant understandings provide the correlations among the nature of active sites, nanostructures, and catalytic activity of M-N-C catalysts at the atomic scale through a combination of experimentation and theory. Current knowledge of the transferring catalytic properties of M-N-C catalysts to MEA performance is limited. Rationally designing morphologic features of M-N-C catalysts play a vital role in boosting electrode performance through exposing more accessible active sites,…

• NS
  National Science Foundation

  Awards: 1804326, CBET-1604392
• UD
  U.S. Department of Energy

  Awards: DE-EE0008075, DE-EE0008417, DE-EE0008076
• OO
  Office of Energy Efficiency and Renewable Energy

  Awards: DE-EE0008417, DE-EE0008075, DE-EE0008076
• DO
  Division of Chemical, Bioengineering, Environmental, and Transport Systems

  Awards: 1604392, CBET-1604392, 1804326
• HA
  Hydrogen and Fuel Cell Technologies Office

  Awards: DE-EE0008417, DE-EE0008076, DE-EE0008075
• OO
  Office of Energy Efficiency