Structure and Properties of VO2 and Titanium Dioxide Based Epitaxial Heterostructures Integrated with Silicon and Sapphire Substrates

The main focus of this study was placed on structure-property correlation in TiO2 and VO2 based epitaxial heterostructures where the photochemical and electrical properties were tuned through microstructural engineering. In the framework of domain matching epitaxy, epitaxial growth of TiO2 and VO2 heterostructures on different substrates were explained. The theta-2theta and ϕ scan X-ray diffraction measurements and detailed high resolution electron microscopy studies corroborated our understanding of the epitaxial growth and the crystallographic arrangement across the interfaces. The influence of the laser and substrate variables on structural characteristics of the films was investigated using X-ray photoelectron spectroscopy, room temperature photoluminescence spectroscopy, and UV-Vis spectrophotometry. In addition, morphological studies were performed by atomic force microscopy. Photochemical properties of the heterostructures were assessed through measuring surface wettability characteristics and photocatalytic reaction rate constant of degradation of 4-chlorophenol under ultraviolet and visible irradiations. We also studied electrical properties employing 4-probe measurement technique. The effect of post treatment processes, such as vacuum annealing and laser treatment, on structure and properties was investigated as well. The role of point defects and deviation from the stoichiometry on photochemical and electrical properties was addressed.;In this research, TiO2 epilayers with controlled phase structure, defect content, and crystallographic alignments were grown on sapphire and silicon substrates. Integration with silicon was achieved using cubic and tetragonal yttria-stabilized zirconia buffer layers. I was able to tune the phase structure of the TiO2 based heterostructures from pure rutile to pure anatase and establish an epitaxial relationship across the interfaces in each case. These heterostructures were used for two different purposes. First, their application in environmental remediation was taken into account. The photochemical efficiency of the samples was evaluated under ultraviolet and visible illuminations. I was able to establish a correlation between the growth conditions and the photocatalytic activity of single crystalline TiO 2 thin films. Visible-light-responsive TiO2 films were fabricated via vacuum annealing of the samples where point defects, namely oxygen vacancies and titanium interstitial, are surmised to play a critical role. An ultrafast switching was observed in wetting characteristics of the single crystalline rutile TiO2 films from a hydrophobic state to a superhydrophilic state by single pulsed excimer laser annealing. It was observed that the laser annealing almost doubles the photocatalytic efficiency of the anatase epitaxial thin films. I was able to measure the photochemical properties of the rutile and the anatase TiO2 heterostructures in a controlled way due to the single crystalline nature of the films. Second, the rutile TiO2 epilayers with different out-of-plane orientations were deposited and used as a platform for VO2 based epitaxial heterostructures with the aim of manipulating of microstructure and electrical properties of the VO 2 films.;Vanadium dioxide (VO2) is an interesting material due to the abrupt change in electrical resistivity and infrared transmittance at about 68 °C. The transition temperature can be tuned through microstructural engineering. It was the idea behind using rutile TiO2 with different crystallographic orientations as a template to tune the semiconductor to metal transition characteristics of the VO2 top layer. I successfully grew VO2(001), VO2(100), and VO2(2¯01) epitaxial thin films on TiO2(100)/c-sapphire, TiO2(101)/r-sapphire, and TiO2(001)/ m-sapphire platforms, respectively. It was observed that tetragonal phase of VO2 was stabilized at lower temperatures leading to a significant decrease in the semiconductor to metal transition temperature. In other words, we were able to tune the transition temperature of the VO 2 epitaxial heterostructures. This achievement introduces the VO 2 based single crystalline heterostructures as a promising candidate for a wide range of applications where different transition temperatures are required. The epitaxial relationships were established and atomic arrangement across the interfaces was studied in detail.