Research

SQS Lab investigates superconducting quantum systems as controllable, engineerable platforms for quantum science and technology.

Our work connects device physics, microwave engineering, nanofabrication, cryogenic measurement, and quantum optics. Current directions include superconducting quantum circuits, waveguide QED, quantum-limited amplification, and hybrid systems that couple microwave fields to mechanical motion.

The lab develops this research together with a close network of collaborators, including Pasquale Scarlino, Vincenzo Savona, Per Delsing, and Tobias J. Kippenberg.

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Waveguide QED

Waveguide QED

We study how superconducting quantum devices exchange photons through engineered microwave environments. Waveguide QED gives us a route to explore collective emission, nonclassical …

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Superconducting Circuits

Superconducting Quantum Circuits

We design, fabricate, and measure superconducting microwave circuits that behave as artificial quantum systems. The lab is interested in high-coherence devices, nonlinear microwave …

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Optomechanics

Hybrid Optomechanics

We explore hybrid devices where superconducting microwave circuits couple to mechanical degrees of freedom. These systems can connect microwave photons, motion, and dissipation in …

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