Research
Electron on Cryogenic Substrate:
Cryogenic noble gases, including liquid helium and solid neon, provide a low-noise host environment for electrons that can be trapped on top of the vacuum interface. In our lab, we utilize this unique feature to develop single-electron qubits for applications in quantum information processing. The system has shown excellent properties, including long coherence, high-fidelity operation, and great scalability.
Nano-Engineered Superconducting Device:
We investigate the physics of cavity quantum electrodynamics, engineer the electromagnetic and phononic interfaces between qubit and its host environment with nano-engineered superconducting devices. We aim to achieve precise manipulation of solid-state qubits and facilitate scalable quantum information technologies.
Complex Photonics:
We explore the application of novel photonic materials and structures for applications in quantum information processing. Specifically, we are interested in the propagation of quantum light in disordered media. Leveraging the concept of entanglement and squeezing, we aim to explore applications in quantum sensing and imaging.
