https://sqs-lab.netlify.app/projects/ResearchHugoBlox Kit (https://hugoblox.com)enhttps://sqs-lab.netlify.app/media/icon_hu_a6f9d0500e0d7ed4.pnghttps://sqs-lab.netlify.app/projects/https://sqs-lab.netlify.app/projects/hybrid-optomechanics/Wed, 20 May 2026 00:00:00 +0000https://sqs-lab.netlify.app/projects/hybrid-optomechanics/<p>We explore hybrid devices where superconducting microwave circuits couple to mechanical degrees of freedom.</p> <p>These systems can connect microwave photons, motion, and dissipation in useful ways, opening paths toward quantum transduction, sensitive force and displacement measurement, and new regimes of macroscopic quantum control.</p>https://sqs-lab.netlify.app/projects/superconducting-quantum-circuits/Wed, 20 May 2026 00:00:00 +0000https://sqs-lab.netlify.app/projects/superconducting-quantum-circuits/<p>We design, fabricate, and measure superconducting microwave circuits that behave as artificial quantum systems.</p> <p>The lab is interested in high-coherence devices, nonlinear microwave elements, parametric interactions, and circuit architectures that make quantum states of microwave fields easier to generate, protect, and detect.</p>https://sqs-lab.netlify.app/projects/waveguide-qed/Wed, 20 May 2026 00:00:00 +0000https://sqs-lab.netlify.app/projects/waveguide-qed/<p>We study how superconducting quantum devices exchange photons through engineered microwave environments.</p> <p>Waveguide QED gives us a route to explore collective emission, nonclassical propagation, photon-mediated interactions, and controlled coupling between localized quantum systems and travelling microwave fields.</p>