It is known that VO₂ epitaxial films grown on (001) TiO₂ single crystal exhibit insulator-to-metal transition (MIT) near room temperature that is much lower than that of bulk VO₂(68 °C). Therefore, VO₂/(001) TiO₂ has attracted attention as a candidate for optoelectronic devices that control electrical conductivity as well as infrared transmission. However, there are several issues to be solved; The critical thickness of VO₂ on (001) TiO₂ is extremely thin (~20 nm), and crack formation occurs upon MIT due to the lattice strain. To address these issues, we examined VO₂/TiO₂ multilayer films.
X-ray reflectivity and out-of-plane XRD patterns of the resultant MLs indicate that the VO₂/TiO₂ MLs were successfully fabricated as designed. Figure 1 shows the ρ−T of the resultant VO₂/TiO₂ MLs. The 8-nm-thick and 40-nm-thick single layer VO₂ exhibit an abrupt and gradual one-step MIT respectively, consistant with previous report. On the other hand, VO₂/TiO₂ MLs shows a stepwise MIT behavior. Moreover, with increasing layer number, the T_c gradually increases accompanied by the disappearance of the stepwise behavior. The stepwise MIT usually suggests the existence of multiphases with different T_c. Figure 2 shows topographic AFM images of the single layer VO₂ and VO₂/TiO₂ ML after heating/cooling cycles. Although some cracks were formed in the case of the 40-nm-thick single layer VO₂ after cycling, the VO₂/TiO₂ ML did not show cracks. These results suggest that multilayer fabrication would be effective to increase the VO₂ thickness and suppress crack formation.