I am currently involved in several research projects, working both independently and in collaboration with experimental groups. My work focuses on understanding and exploring complex quantum phenomena in advanced material systems. The key topics I am investigating include:
Quantum Geometry of Spin-Wave Systems in Layered Magnets
Currently I am actively working on the quantum geometry of spin waves in layered magnets and aim to identify signatures that can be measured experimentally, connecting theory with potential spintronic applications.
Topological Properties in Parity-Time (PT) Invariant Materials
I explore the emergence of topological phases in materials with parity-time symmetry, focusing on their unique electronic and optical properties and potential applications. Specifically, I investigate these properties in systems such as twisted bilayer graphene, using them as a model platform to study novel topological effects.
Ferroelectric Properties in Transition Metal Dichalcogenide-Based Moiré Systems
I investigate ferroelectric behavior in twisted trilayer TMD materials, with a particular focus on how stacking configurations and external electric fields affect domain wall dynamics. This research aims to uncover the microscopic mechanisms governing ferroelectricity and its tunability in moiré systems.
Exciton Diffusion Dynamics in Transition Metal Dichalcogenide-Based Moiré Systems Under Strain
I study the effect of external strain on exciton diffusion in TMD-based heterobilayers, emphasizing the interplay between strain, moiré potential, and excitonic properties. A key question driving this research is whether external strain can be harnessed to create efficient transport channels for exciton particles, enhancing their mobility and coherence.