In this thesis, synchrotron-based x-ray magnetic spectroscopy was intensively utilized to explore the interface-driven magnetic properties in spintronic materials. , We first report on the successful fabrication of epitaxial-discrete Co1−XFe2+XO4/CoO magnetic nanostructures on a SrTiO3 substrate, where the cross-reactions of the two magnetic phases in the vicinity of the epitaxial junction were thoroughly investigated. These nanostructures were originally prepared as Fe3O4-CoO core-shell structures through the phase decomposition of bismuth perovskite precursors by pulsed-laser deposition. An antiphase boundary emerged during the structural/electronic transition from the CoO core to the Co1−XFe2+XO4 shell; thereby developing a ferrimagnetic/antiferromagnetic interface. Uncompensated spins (UCS) arose from the Co1−XFe2+XO4/CoO interface as a result of strong ferrimagnetic–antiferromagnetic interactions. A notable exchange bias as well as a significant exchange enhancement was observed owing to the UCS, which had a locking effect because of the decoupling of the Co1−XFe2+XO4/CoO reversal from the antiphase boundary. Control of the precursor ratio allowed for the fine-tuning of the Co1−XFe2+XO4 phase and the associated locking behaviors. This, in turn, allowed the anisotropy and coercivity of the nanostructures to be manipulated. Thus, we were able to create and thoroughly understand a complex epitaxial configuration with tunable structural and magnetic properties. This study should open new opportunities with regard to current magnetic oxide technology, which requires novel methods for pursuing extremity of controllable properties over an atomic landscape. In second project, we investigated the emerging magnetism at a ferromagnet/topological-insulator heterostructure. Introducing ferromagnetism at the surface of a topological insulator (TI) could enable fascinating spin-charge phenomena that possess great value for related technology. Such fascinating physics was presumed being associated with a homogeneous ferromagnetic (FM) layer with one type magnetic order. By synchrotron x-ray and microstructural analyzes we observed phase separation within the FM layer of a Ni80Fe20/Bi2Se3 heterostructure. The phase separation was caused by significant diffusion of Ni into Bi2Se3 that formed a ternary magnetic phase of Ni:Bi2Se3. The inward diffusion of Ni led to the development of FeSe phase outward, hence turning original Ni80Fe20/Bi2Se3 into a sandwiched structure of FeSe/Ni:Bi2Se3/Bi2Se3 featuring dual magnetic phase. The TI’s properties were well preserved despite the dual magnetic phase, which explained why it was overlooked in previous studies. By spin-orbit energy calculation FeSe and Ni:Bi2Se3 were found to possess in-plane and out-of-plane magnetic anisotropy, respectively. The heterostructure’s magnetic order could be readily tuned by Bi2Se3 thickness as compromising the magnetic orders of the two magnetic phases. The discovery is essential to the quantification of critical spin-charge phenomena, such as spin-transfer torque, spin-orbit torque, spin pumping, and quantum anomalous Hall effect, in similar material combinations, of which the FM layer is composed of multi-element. Third, using x-ray magnetic spectroscopy with in-situ electrical characterizations, we investigated the effects of external voltage on the spin-electronic and transport properties at the interface of a Fe/ZnO device. Layer-, element-, and spin-resolved information of the device was obtained by cross-tuning of the x-ray mode and photon energy, when voltage was applied. At the early stage of the operation, the device exhibited a low-resistance state featuring robust Fe-O bonds. However, the Fe-O bonds were broken with increasing voltage. Breaking of the Fe-O bonds caused the formation of oxygen vacancies and resulted in a high-resistance state. Such interface reconstruction was coupled to a charge transfer effect via Fe-O hybridization, which suppressed/enhanced the magnetization/coercivity of Fe electronically. Nevertheless, the interface became stabilized with the metallic phase if the device was continuously polarized. During this stage, the spin-polarization of Fe was enhanced whereas the coercivity was lowered by voltage. This stage is desirable for spintronic device applications, owing to a different voltage-induced electronic transition compared to the first stage. The study enabled a straightforward detection of the spin-electronic state at the ferromagnet-semiconductor interface in relation to the transport and reversal properties during the operation process of the device.