Description: Trapping single neutral atoms in high-finesse optical or fibre-tip microcavities for deterministic single-photon generation and strong light-matter coupling.
Parigi co-leads the Multimode Quantum Optics group at LKB alongside Treps. Research directions: (1) Multimode squeezed-state quantum networks — generating large-scale entangled cluster states using optical frequency combs; reconfigurable graph-state topologies for measurement-based quantum computing and distributed quantum sensing; (2) Multimode quantum sensing — using multimode squeezed states for simultaneous beyond-shot-noise estimation of multiple parameters (wavelengths, phases) in a spectrometer; (3) Non-Gaussian quantum states — heralded subtraction and addition of photons to Gaussian cluster states for universal CV quantum computation; (4) Quantum networks at telecom — generating multimode squeezed states compatible with fiber transmission. ERC Laureate. Employed by Sorbonne Université.
Stefan Schäffer leads the Quantum Metrology group at NBI together with Jörg Müller. Research focuses on superradiant strontium lasers: (1) quasi-continuous superradiant lasing with sub-natural linewidth; (2) Ramsey spectroscopy enhanced by cavity sub-to-superradiant phase transitions for improved atomic clock sensing; (3) continuous atom beam for Dicke-effect-free superradiant interrogation. Key work published in PRL (2023) and Nature Communications (2024). Part of EU iqClock and ESA collaborations.
Schleier-Smith's group uses optical-cavity-mediated interactions to entangle and spin-squeeze ensembles of trapped neutral atoms, generating metrologically useful entangled states for quantum-enhanced sensing, and is developing modular, networked atom-cavity systems as building blocks for distributed quantum sensor arrays and simulators.
Simon's lab engineers strong, atom-mediated interactions between photons in optical cavities -- using Rydberg dressing of intracavity atoms -- to synthesize interacting quantum photonic matter and study fundamental nonclassical light phenomena, effectively building tunable many-body systems out of light itself.
Builds neutral-atom-array platforms coupled to optical cavities to explore nonlocal entanglement for modular fault-tolerant quantum computing and distributed quantum sensor networks; also works on quantum error correction and quantum foundations.