Catalytically Stable Potassium Single‐Atom Solid Superbases

Solid superbases can catalyze diverse reactions under mild conditions, while they suffer from aggregation of basic sites and poor stability during recycling. Here we report a new generation of solid superbases derived from K single atoms (SAs) prepared by a tandem redox strategy. The initial redox reaction takes place between base precursor KNO3 and graphene support, producing K2O at 400 °C. Further increasing the temperature to 800 °C, the graphene reduces K2O to K anchored by its vacancies, leading to the generation of K SAs (denoted as K1/G). The source of basicity in the K1/G is K SAs, and neighboring single atoms (NSAs) possess superbasicity, which is different from conventional basicity originated from oxygen and nitrogen atoms. Due to the superbasicity as well as high dispersion and anchoring of basic sites, the K1/G shows excellent catalytic activity and stability in transesterification reaction, which is much superior to the reported catalysts. A new generation of solid superbase derived from potassium single atoms anchored on graphene is developed by a tandem redox strategy. The source of the basicity is the single K atoms, thus differing from conventional basicity which originates from oxygen and nitrogen atoms. The high dispersion and anchoring of superbasic sites endows the catalyst with excellent activity and stability in transesterification reactions.