Carbon nanomaterials have abundant sources but are difficult to use directly as a support for single atom catalysts (SACs) due to the lack of strong anchoring forces to restrict the movement and aggregation of metal atoms during the high-temperature heat treatment. Herein, we report a "self-catalysis"method for the synthesis of ferrous metal single-atom catalysts (SACs) FM-N-C (FM = Fe, Co, and Ni) with ∼2 wt% metal loadings on a carbon black support. The combination of experimental and theoretical evidence reveals a self-catalytic process from FM atoms to FM-N4 species, which involves (1) the adsorption of FM ions on the surface-oxidized carbon nanoparticles via oxygen coordination bonds (FM-O); (2) the catalytic decomposition of ammonia to nitrogen radicals on the FM atoms; (3) the replacement of coordinating oxygen with nitrogen. The precoordination of FM with oxygen is the key to the synthesis and reduces the energy barrier of ammonia decomposition and nitrogen bonding to the FM atoms. Thus, the formation of the FM-N4 species at a mild temperature of 600 °C is enabled. The as-synthesized FM-N-C SACs exhibit high catalytic activities towards O2 and/or CO2 reduction reactions. In contrast to the metal-organic framework-based SACs in which the MOF support significantly changes in size and weight, the self-catalysis technique is "minimally invasive"to the carbon support, thus benefiting the structural design of SACs by taking advantage of the abundant morphologies of the carbon nanomaterials. This journal is
Bibliographical noteKAUST Repository Item: Exported on 2020-10-01
Acknowledgements: This work was supported by the National Natural Science Foundation of China (21673014, 21975010 and 51920105001).