Exploring Spin Dependent Phenomena, Interfaces, Magnetic Chiral Structures, and Quantum Materials for Next-Generation Information Technologies
The Quantum Spintronics Laboratory performs interdisciplinary research combining condensed matter physics, nanotechnology, materials science and artificial intelligence to develop next-generation spin-based electronic devices.
Design and fabrication of high-performance magnetic tunnel junctions for MRAM, spin logic and magnetic sensing technologies.
Experimental realization altermagnetic tunnel junctions with AI-assisted materials engineering.
Investigation of spin transport, Inverse spin Hall effect, Rashba-Edelstein effect and interface magnetism in topological systems.
Study of topological spin textures for future neuromorphic computing and ultra-low-power memory technologies.
Generation and manipulation of pure spin currents through ferromagnetic resonance and spin-orbit coupling phenomena.
Integration of machine learning with experimental physics for intelligent optimization of spintronic materials and devices.
Q-SPIN LAB aims to become a globally recognized research center in Spintronics, Quantum Materials, Altermagnetism and Artificial Intelligence driven Materials Science by fostering interdisciplinary collaborations and high-impact scientific discoveries.