Inspired by single-atom electrocatalysts, the project integrated covalent-organic frameworks and graphdiyne, achieved a novel conductive metal covalent-organic frameworks (MCOFs) catalyst toward water splitting. The new MCOFs increased the metal content of SACs to ~ 2 at%, which is much higher than that of traditional SCAs (≤ 1 at%), the abundant active metal centers will bring a huge improvement of electrocatalytic performance for MCOFs. Moreover, by engineering chemical composition, a series of MCOFs with different metal center was synthesized. The corresponding physical properties (chemical structure, optical and electrical properties) were investigated by various technologies, including scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDS), X-ray diffraction (XRD), infrared spectrometer and UV absorption spectrum. Additionally, the electrochemical investigation displayed that the new MCOFs with high metal content has a good HER behavior.
In order to reveal the catalytic mechanism of SACs, the ER cooperated with several well-known research groups worldwide. By starting with traditional inorganic nanocatalysts, the catalytic mechanism of SACs toward water splitting has been gradually clarified. That laid the foundation of establishing a mechanism platform toward SCAs catalysis, which will re-defining the concept of next-generation electrocatalysts. The mechanism platform will contribute to the development of hydrogen and other electrochemical industries.