Research Areas - (169) Quantum Optics

Full path: Physics > Quantum Optics

Department(s)/lab(s): Physics | LKB - Rydberg Atoms Team @ CNRS
Summary:

Gleyzes is a CNRS researcher in the Rydberg Atoms team at LKB (successor to Serge Haroche's cavity-QED group), where he achieved the first quantum non-demolition detection of a single microwave photon. The team now prepares non-classical states of circular Rydberg atoms as probes for electric- and magnetic-field sensing below the standard quantum limit, uses quantum optimal control to navigate large Rydberg Hilbert spaces, and has demonstrated millisecond-lived circular states at room temperature, a route toward practical Rydberg-atom quantum sensors and simulators.

Department(s)/lab(s): Physics – Laboratoire Kastler Brossel, Sorbonne UniversitΓ© | Quantum Fluids of Light Group (Glorieux Group / LKB) @ Sorbonne
Summary:

Glorieux leads the Quantum Fluids of Light and Nanophotonics group at LKB. Research directions: (1) Quantum fluids of light in atomic vapors β€” hot Rb/Cs vapor as paraxial photon fluids exhibiting superfluidity, soliton dynamics, and vortex formation; first analogue cosmological particle creation (Hawking effect) in a photon fluid (Nature Communications 2022); (2) Polariton superfluids β€” exciton-polariton microcavities for analogue gravity, Bogoliubov dispersion mapping, and first-order dissipative phase transitions; (3) Nanophotonics β€” coupling single quantum emitters (nanofiber-coupled atoms, perovskite nanocrystals) for quantum photonics and sensing; displacement sensor based on optical nanofiber; (4) Optical computing interfaces with quantum systems. Marie Curie IOF Fellow (2011), City of Paris Young Scientist Award (2015).

Department(s)/lab(s): Physics / LKB | Quantum Fluids of Light Group (Glorieux Lab) @ ENS Paris
Summary:

Quentin Glorieux's group explores quantum fluids of light and polariton physics. Research: (1) exciton-polariton condensates in semiconductor microcavities β€” superfluidity, vortex dynamics, analogue gravity; (2) quantum fluids of light in atomic media β€” photon-photon interactions via electromagnetically induced transparency; (3) analogue gravity with polariton and photon fluids β€” studying acoustic black hole analogs with quantum light. IUF member; ERC grants.

Department(s)/lab(s): Physics | LuMIn - Lasers, Atomic & Quantum Optics (Bretenaker/Goldfarb) @ ENSPS
Summary:

Goldfarb studies coherent effects in atomic vapours - EIT and slow light, spin-noise spectroscopy of spin-environment interaction, and EIT-based Rydberg-atom radio-frequency field sensing (electrometry) in warm cells. In the broader landscape of NV-centre ensemble quantum sensing (DEER, nano-NMR, T1 relaxometry) operating near pT/sqrt(Hz) sensitivity, this work adds atomic-vapour electrometry and coherence spectroscopy.

Department(s)/lab(s): Physics | Goldschmidt Research Group @ UIUC
Summary:

Studies experimental quantum optics and atomic physics, including quantum light-matter interfaces, quantum memories, and single-photon sources based on atom-like emitters in solids, for applications in long-distance quantum communication and quantum networking.

Department(s)/lab(s): Physics – Institute for Quantum Electronics | Optical Nanomaterial Group (Grange) @ ETH Zurich
Summary:

Grange leads the Optical Nanomaterial Group at ETH, developing nonlinear materials for quantum photonic integrated circuits. Research directions: (1) Barium titanate (BTO) nanophotonics β€” scalable CMOS-compatible BTO thin-film integrated circuits exploiting large Ο‡(2) nonlinearity for quantum entangled photon-pair generation via SPDC; (2) Lithium niobate on insulator (LNOI) β€” quantum photonic integrated circuits for heralded single-photon sources and electro-optic transduction; (3) Second-harmonic generation sensing β€” SHG-active nanocrystals as contrast agents and phase-sensitive probes in biological imaging; (4) On-chip entangled photon sources for quantum communication and sensing. Strong quantum sensing application in nonlinear optical readout of quantum states.

Department(s)/lab(s): Physics / Laboratoire Charles Fabry (IOGS/X) | Quantum Optics Group LCF (Grangier Lab) @ X
Summary:

Philippe Grangier is a pioneer of quantum optics and quantum information at the Laboratoire Charles Fabry (IOGS/Γ‰cole Polytechnique). Research: (1) foundations of quantum mechanics: single photon experiments, Bell tests, quantum non-demolition measurement; (2) quantum optics and quantum information β€” continuous variables, entanglement generation, quantum cryptography; (3) Rydberg atom experiments (in collaboration with Browaeys). Coordinator of SIRTEQ network (700+ quantum researchers in Île-de-France). Closely connected to Pasqal spinoff. Key for quantum sensing foundations.

Department(s)/lab(s): Quantum Nanoscience | Groeblacher Lab @ TU Delft
Summary:

Simon Groeblacher's lab probes quantum physics at meso- and macroscopic scales using mechanical motion, rare-earth ion emitters, and superconducting qubits. Key research directions: (1) quantum optomechanics with photonic crystal nano-beam resonators deep in the resolved-sideband regime; (2) silicon defect emitters (rare-earth doped silicon) for quantum network nodes; (3) quantum acoustics experiments coupling mechanical resonators to superconducting qubits. The lab fabricates all devices in-house at Kavli Nanolab and has received NWO Summit Grant for 'Quantum Limits' and QDNL/NWO grant for quantum network nodes.

Department(s)/lab(s): Physics – Institute of Physics (IPHYS) / CIBM | Laboratory for Functional and Metabolic Imaging (Gruetter Group, CIBM) @ EPFL
Summary:

Gruetter leads the Laboratory for Functional and Metabolic Imaging (LFMI) at EPFL and co-directs the CIBM (Centre for Biomedical Imaging). Research directions: (1) Ultra-high-field in vivo MR spectroscopy β€” developing 1H, 13C, 31P, 23Na MRS at 14.1T animal and 7T human systems to measure metabolite concentrations (glutamate, GABA, lactate) in brain with unprecedented sensitivity; (2) Quantum coherence effects in NMR β€” exploiting J-coupling evolution and JPRESS sequences for quantum-selective metabolite editing; (3) Hyperpolarization β€” DNP-enhanced metabolite sensing in vivo for tracking metabolic flux in real time; (4) Neuroimaging β€” quantitative BOLD fMRI calibration and cerebral blood flow mapping. The 14.1T magnet is among the world's most powerful for biological NMR spectroscopy.

Tags:
Department(s)/lab(s): Physics (LKB) | Optomechanics and Quantum Measurements Team @ ENS Paris
Summary:

Guerlin works on quantum-limited optomechanical measurement and quantum non-demolition detection schemes within LKB's optomechanics team, building on cavity-QED-style quantum-measurement concepts applied to mechanical degrees of freedom.