Catalytic decomposition of SiO₂ by Fe and the effect of Cu on the behavior of released Si species

Si supply mechanism in the spontaneous formation of SiO₂ pattern on a Cu foil, which was previously reported to enable the selective growth of graphene in no direct contact with organic materials, was investigated. Upon annealing at 1000°C and atmospheric pressure, SiO₂ in the Fe-coated SiO₂/Al₂O₃ template covered by a Cu foil was found to be severely decomposed by Fe droplets. No signature of reaction between SiO₂ and Fe droplets suggested that Si species, which contributed to the spontaneous formation of SiO₂ pattern on a Cu foil, originated from SiO₂ catalytically decomposed by Fe droplets. In the absence of a Cu foil covering an Fe-coated SiO₂/Al₂O₃ template, the catalytic activity of Fe droplets was significantly suppressed because of the encapsulation of Fe droplets by a 2-nm-thin-Fe₃O₄ layer. Furthermore, a part of the Fe film on SiO₂/Al₂O₃ without a Cu foil turned into nanodroplets and assisted the formation of SiO₂ nanowires. These results reveal that a Cu foil made an intriguing role in preventing Fe from being encapsulated by Fe₃O₄, so the catalytic role of Fe droplets was not terminated until SiO₂ was fully decomposed. Our experimental results provided insights into better understanding of these intriguing behaviors of Fe and Cu on SiO₂ at high temperature and at atmospheric pressure.