Abstract
Vanadium dioxide (VO2) is an archetypal metal-insulator transition (MIT) material, which has been known for decades to show an orders-of-magnitude change in resistivity across the critical temperature of approximately 340 K. In recent years, VO2 has attracted increasing interest for electronic and photonic applications, along with advancement in thin film growth techniques. Previously, thin films of VO2 were commonly grown on rigid substrates such as crystalline oxides and bulk semiconductors, but the use of transferrable materials as the growth substrates can provide versatility in applications, including transparent and flexible devices. Here, we employ single-crystalline hexagonal boron nitride (hBN), which is an insulating layered material, as a substrate for VO2 thin film growth. VO2 thin films in the polycrystalline form are grown onto hBN thin flakes exfoliated onto silicon (Si) with a thermal oxide, with grains reaching up-to a micrometer in size. The VO2 grains on hBN are orientated preferentially with the (110) surface of the rutile structure, which is the most energetically favorable. The VO2 film on hBN shows a MIT at approximately 340 K, across which the resistivity changes by nearly three orders of magnitude, comparable to VO2 films grown on common substrates such as sapphire and titanium dioxide. The VO2/hBN stack can be picked up from the supporting Si and transferred onto arbitrary substrates, onto which VO2 thin films cannot be grown directly. Our results pave the way for new possibilities for practical and versatile applications of VO2 thin films in electronics and photonics.
Highlights
(hBN), which is an insulating layered material, as a substrate for VO2 thin film growth
By using cross-sectional scanning transmission electron microscopy (STEM), we find that the thicknesses of films supported on SiO2 and hexagonal boron nitride (hBN) are comparable to each other
The VO2 thin film is grown preferentially with the (110) orientation, which is predicted by the DFT calculation to be the most energetically stable[38]
Summary
(hBN), which is an insulating layered material, as a substrate for VO2 thin film growth. Non-oxide materials have been employed as substrates for VO2 growth, such as silicon (Si)[8], germanium[9], and gallium nitride[10] Even on such semiconducting compounds, VO2 films show reasonable MIT properties, opening the possibility for the realization of electronic and photonic VO2 devices compatible with existing semiconductor technology. Thin films of muscovite could be peeled off from the bulk with the covering VO214, promising flexible device applications These results suggest the utility of layered materials for the VO2 growth substrate, their potential applications may be limited in number because graphene shows an extremely high electrical conductivity, while muscovite is mechanically relatively fragile. The search for alternative layered materials with insulating properties as well as mechanical strength is necessary for realizing more versatile applications
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