Litcius/Paper detail

Axially Modified Square-Pyramidal CoN<sub>4</sub>–F<sub>1</sub> Sites Enabling High-Performance Zn–Air Batteries

Daili Cao, Yuewen Mu, Lijia Liu, Zhixing Mou, Shuai Chen, Wenjun Yan, Haiqing Zhou, Ting‐Shan Chan, Lo‐Yueh Chang, Li Song, Hua‐Jin Zhai, Xiujun Fan

2024ACS Nano49 citationsDOI

Abstract

Cobalt–nitrogen-carbon (Co–N–C) catalysts with a CoN 4 structure exhibit great potential for oxygen reduction reaction (ORR), but the imperfect adsorption energy toward oxygen species greatly limits their reduction efficiency and practical application potential. Here, F-coordinated Co–N–C catalysts with square-pyramidal CoN 4 –F 1 configuration are successfully synthesized using F atoms to regulate the axial coordination of Co centers via hydrothermal and chemical vapor deposition methods. During the synthesis process, the geometry structure of the Co atom converts from six-coordinated Co–F 6 to square-pyramidal CoN 4 –F 1 in the coordinatively unsaturated state, which provides an open binding site for the O 2 . The introduction of axial F atoms into the CoN 4 plane alters the local atomic environment around Co, significantly improving the ORR activity and Zn–air batteries performance. In situ spectroscopy proves that CoN 4 –F 1 sites strongly combine with the OOH* intermediate and facilitate the splitting of O–O bond, making OOH* readily decompose into O* and OH* via a dissociative pathway. Theoretical calculations confirm that the axial F atom effectively reduces the electronic density of the Co centers and facilitates the desorption of the OH* intermediate, efficiently accelerating the overall ORR kinetics. This work advances a feasible synthesis mechanism of axial ligands and provides a route to construct efficient high-coordination catalysts.

Topics & Concepts

CatalysisDesorptionMaterials scienceAdsorptionChemistryNanotechnologyPhysical chemistryBiochemistryElectrocatalysts for Energy ConversionAdvanced battery technologies researchCatalytic Processes in Materials Science