Quantum Materials & Topological Superconductivity

I study quantum materials where topology, superconductivity, spin–orbit coupling, and coherence produce unusual transport and device behavior. My recent work focuses on Fe(Te,Se)-based mesoscopic superconducting devices, where I build theory to explain experimental signatures and uncover the microscopic mechanisms behind topological and superconducting phenomena.

Topological and Nonequilibrium Transport

I am interested in how topology, symmetry, strain, chirality, and external driving shape transport in quantum materials. My work includes Hall viscosity, nonlinear Hall effects, chiral photocurrents, domain-wall dynamics, and coherent interference all as ways of revealing deeper quantum structure through transport.

Computational Modeling & Numerical Simulation

I develop model Hamiltonians and numerical simulations to study transport, coherence, nonlinear response, and open-system dynamics in condensed matter and quantum systems. I enjoy using computation as a bridge between theory and experiment, turning physical intuition into testable predictions.

Quantum Simulation & Open Quantum Systems

I also work on quantum simulation and open quantum systems, with interests in decoherence, noise, Lindblad dynamics, and Trotterized evolution. This work reflects my broader interest in understanding realistic quantum systems and connecting fundamental theory to emerging quantum technologies.