Engineering Local and Global Structures of Single Co Atoms for a Superior Oxygen Reduction Reaction

Citations Over TimeTop 10% of 2020 papers

Abstract

The ability to tune both local and global environments of a single-metal active center on a support is crucial for the development of highly robust and efficient single-atom electrocatalysts (SAECs) that can surmount both thermodynamic and kinetic constraints in electrocatalysis. Here, we designed a core–shell-structured SAEC (Co1-SAC) with superior oxygen reduction reaction (ORR) performance. Co1-SAC consists of a locally engineered single Co-N3C1 site on a N-doped microporous amorphous carbon support enveloped by a globally engineered highly conductive mesoporous graphitic carbon shell. Theoretical calculations reveal that Co-N3C1 exhibits near-Fermi electronic states distinct from those of Co-N2C2 and Co-N4, which facilitate both the electronic hybridization with O2 and the subsequent protonation of adsorbed O2* toward the formation of OOH*. Engineering Co-N3C1-SAC into a micro/mesoporous core–shell structure dramatically enhances the mass transport and electron transfer, which further boosts the ORR and Zn-air battery performance (slightly outperforming Pt/C). Our findings open an avenue toward engineering of the local and global environment of SACs for a wide range of efficient electrochemical conversions.

Related Papers

• → Electrochemically Exfoliated β-Co(OH)₂ Nanostructures for Enhanced Oxygen Evolution Electrocatalysis(2020)74 cited
• → High efficiency electrocatalyst of LaCr0.5Fe0.5O3 nanoparticles on oxygen-evolution reaction(2020)35 cited
• → Co–Fe–P Nanosheet Arrays as a Highly Synergistic and Efficient Electrocatalyst for Oxygen Evolution Reaction(2022)27 cited
• → Nd₆Ir₂O₁₃ as an Efficient Electrocatalyst Boosts the Oxygen Evolution Reaction in Acidic Media(2022)25 cited
• → Electrocatalyst of RuO2 decorating TiO2 nanowire arrays for acidic oxygen evolution(2022)24 cited