Oxidation mechanism in metal nanoclusters: Zn nanoclusters to ZnO hollow nanoclusters

Zn nanoclusters (NCs) are deposited by the low-energy cluster beam deposition technique. The mechanism of oxidation is studied by analysing their compositional and morphological evolution over a long span of time (three years) due to exposure to ambient atmosphere. It is concluded that the mechanism proceeds in two steps. In the first step, the shell of ZnO forms over Zn NCs rapidly up to a certain limiting thickness: within a few days-depending upon the size-Zn NCs are converted to Zn-ZnO (core-shell), Zn-void-ZnO, or hollow ZnO type NCs. Bigger than similar to 15 nm become Zn-ZnO (core-shell) type: among them, NCs above similar to 25 nm could retain their initial geometrical shapes (namely triangular, hexagonal, rectangular and rhombohedral), but similar to 25 to 15 nm size NCs become irregular or distorted geometrical shapes. NCs between similar to 15 to 5 nm become Zn-void-ZnO type, and smaller than similar to 5 nm become ZnO hollow sphere type, i.e. ZnO hollow NCs. In the second step, all Zn-void-ZnO and Zn-ZnO (core-shell) structures are converted to hollow ZnO NCs in a slow and gradual process, and the mechanism of conversion proceeds through expansion in size by incorporating ZnO monomers inside the shell. The observed oxidation behaviour of NCs is compared with theory of Cabrera-Mott on low-temperature oxidation of metal.