Research Areas
Our research encompasses full-stack integration from fundamental material growth to advanced quantum circuit architectures.
1. Superconducting Qubits
Developing high-performance superconducting quantum circuits, including the optimization of transmon architectures and the advancement of Fluxonium qubits for higher anharmonicity and longer coherence times.
2. Hybrid Superconducting Quantum Circuits
Integrating graphene and topological materials into superconducting circuits to explore gate-tunable qubits (Gatemons) and novel 3D transmon configurations.
3. Quantum Optics & Theory
Focusing on theoretical models for neutral atom systems and their potential applications in quantum optics, simulation, and quantum information theory.
4. Quantum Materials: Theory, Analysis & Synthesis
Involving band structure calculations of topological materials, Chemical Vapor Deposition (CVD) growth of 2D materials, and precise physical property characterization.
5. Topological Josephson Junction Devices
Fabrication of Josephson junctions based on topological materials to develop robust components for topological quantum computing.