Morphological Evolution of Grain-Boundary SiO₂ in Internally Oxidized Cu-Si Bicrystals

Abstract

Cu-0.78 mass%Si bicrystals are internally oxidized at various conditions and morphological evolution of amorphous SiO₂ formed on a grain boundary (GB) is observed. After the reaction of Si atoms with oxygen, a film-like SiO₂ phase with holes is initially formed on GB of Cu. At temperatures used for the internal oxidation, the holes rapidly grow and the morphology of the film-like SiO₂ changes to a particulate equilibrium shape through formation of two-dimensional SiO₂ network and its subsequent breakup. During the morphological evolution, the volume of SiO₂ on GB is conserved. The morphological evolution of SiO₂ on GB is caused by diffusional flow of matter to decrease the sum of Cu/SiO₂ interface and Cu grain-boundary energies. The activation energy Q of the morphological evolution is obtained as Q ≈ 290 kJ/mol. Among the values of activation energies reported in the previous studies on diffusion in SiO₂, Q ≈ 290 kJ/mol is close to that for the volume-diffusion of SiO in SiO₂, Q_SiO ≈ 268 kJ/mol. This supports that the morphological evolution of SiO₂ on GB is controlled by the volume-diffusion of SiO in SiO₂.