Effect of microplate size on the semiconductor-metal transition in VO2 thin films

VO2 thin films composed of irregularly shaped microplates have been synthesized using V2O5 as a precursor via the vapor transport technique. SEM images showed that the microplate sizes in VO2 films tended to increase (from 16 to 51 mu m) with increasing quantity of V2O5 precursor due to the large nuclei of VO2 crystals formed at the initial growth stage under a relatively large amount of precursor. Raman, XRD and XPS analysis collectively demonstrated that these film structures have high crystal quality of monoclinic VO2 phase. Furthermore, the thermally driven phase transition was investigated by measuring the electrical resistance during the heating and cooling process. All the films exhibited a typical semiconductor-metal transition at 340 K, and the highest resistivity change reached 4.2 decades. More significantly, the phase transition behaviors show a noticeable variation in the amplitude of the resistivity change, which becomes more prominent as the VO2 film microplate size grows. The relevant mechanism is considered to be predominantly associated with the electron scattering attenuation effect, related to a decrease in the grain boundary density as the microplate size of the VO2 films grows. Additionally, a device based on a high-quality VO2 thin film exhibits efficient IR response, with high responsivity (similar to 12.5 mA W-1) and fast response speed (similar to 40 ms) under ambient conditions, which should be promising for sensitive IR detection.

Automated summary

VO2 thin films composed of irregularly shaped microplates have been successfully synthesized using V2O5 as a precursor via vapor transport technique. These films exhibit high crystal quality of monoclinic VO2 phase and show interesting phase transition behavior and infrared response.