Our group studies how engineered superconducting circuits can generate, route, amplify, and measure fragile quantum states of microwave light and motion.
We combine nanofabrication, cryogenic microwave measurement, quantum-limited amplification, and theory-guided device design to build platforms for quantum information processing, sensing, and many-body physics.
Qubit: Fluxonium
Superconducting Circuits
Engineering high-coherence superconducting devices and qubits for quantum information and sensing.
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Electromechanical Hexamer
Hybrid Optomechanics
Controlling mechanical motion at the quantum level using superconducting circuits and collective effects.
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TWPA implemented by 2000 JJ transmission line
Waveguide QED
Shaping light-matter interaction in superconducting waveguides for quantum-limited amplification and photon manipulation.
Learn more →We also welcome curious students and researchers interested in superconducting quantum circuits, waveguide QED, microwave measurements, nanofabrication, and hybrid quantum systems.