| Complex oxides are a class of materials that exhibit a wide variety of physical functionalities, such as ferroelectricity, colossal magnetoresistance, mulitferroicity and superconductivity, with outstanding potential for meeting many of our technological demands. The primary objective of this dissertation is to understand the structural and electronic behavior of complex oxide ultrathin films subjected to confinement, lattice misfit and broken symmetry at the interface. In complex oxide ultrathin films, heteroepitaxial synthesis has evolved into a reliable strategy to engineer orbital-lattice interactions in correlated materials and led to new and entirely unexpected phenomena at their interfaces. I experimentally demonstrated that the bulk crystal symmetry directs the atomic and orbital responses adopted by coherently strained ultrathin films of RNiO3 (R = La, Nd) with detailed X-ray scattering, polarization-dependent X-ray absorption spectroscopy (XAS) and supported by a mathematical point group symmetry analysis, found that strain-stabilized phases maintain a ``memory'' of their bulk state. This topic, however, touched only upon the properties of such films. A fundamental challenge in this research area occurs before this and centers around the understanding of how to create high-quality films with arbitrary configurations. A longstanding challenge in the oxide thin film community has been the growth of An+1BnO3 n+1 Ruddlesden-Popper (RP) compounds. To understand this problem, we have utilized a newly constructed oxide MBE with in situ synchrotron X-ray scattering capability to study the initial growth of such layered oxides and track the dynamic evolution. X-ray results are supported by theoretical calculations that demonstrated the layered oxide films dynamically rearrange during growth, leading to structures that are highly unexpected, and suggest a general approach that may be essential for the construction of metastable RP phases with performing the first atomically controlled synthesis of single-crystalline La3Ni2O7. By building upon this knowledge, I have completed the first to date study of in situ surface X-ray scattering during homoepitaxial MBE growth of SrTiO3, which demonstrates codeposition is consistent with a 2D island growth mode with SrTiO3 islands, but shuttered deposition proceeds by the growth of SrO islands which then restructure into atomically flat SrTiO3 layer during the deposition of the TiO2. From this point, we have conducted a detailed microscopic study of epitaxial LaNiO3 ultrathin films grown on SrTiO3 (001) by using reactive MBE with in situ surface X-ray diffraction and ex situ soft XAS to explore the influence of polar mismatch on the resulting structural and electronic properties. Overall, this thesis highlights the power of artificial confinement to harness control over competing phases in complex oxides with atomic-scale precision. |
