Hybrid Nanocarbon as a Catalyst for Direct Dehydrogenation of Propane: Formation of an Active and Selective Core–Shell sp2/sp3 Nanocomposite Structure

Hybrid nanocarbon, comprised of a diamond core and a graphitic shell with a variable sp²‐/sp³‐carbon ratio, is controllably obtained through sequential annealing treatment (550–1300 °C) of nanodiamond. The formation of sp² carbon increases with annealing temperature and the nanodiamond surface is reconstructed from amorphous into a well‐ordered, onion‐like carbon structure via an intermediate composite structure—a diamond core covered by a defective, curved graphene outer shell. Direct dehydrogenation of propane shows that the sp²‐/sp³‐nanocomposite exhibits superior catalytic performance to that of individual nanodiamond and graphitic nanocarbon. The optimum catalytic activity of the diamond/graphene composite depends on the maximum structural defectiveness and high chemical reactivity of the ketone groups. Ketone‐type functional groups anchored on the defects/vacancies are active for propene formation; nevertheless, once the oxygen functional groups are desorbed, the defects/vacancies alone might be active sites responsible for the C?H bond activation of propane.