Research Areas - (8) Optical Atomic Sensing

Full path: Physics > AMO Physics > Optical Atomic Sensing

Department(s)/lab(s): Physics / LKB | Cavity QED Group (Brune/Raimond) @ ENS Paris
Summary:

Michel Brune leads the Rydberg atoms / cavity QED group at LKB. Research: (1) circular Rydberg atoms trapped in high-finesse microwave cavities — quantum non-demolition measurement of photons, quantum state engineering; (2) fundamental quantum optics: decoherence, entanglement, quantum jumps, Schrödinger cat states; (3) quantum sensing of cavity fields with single atoms as probes. This group pioneered cavity QED experiments leading to the 2012 Nobel Prize (Haroche). Brune heads the laboratory.

Department(s)/lab(s): Physics / Laboratoire Charles Fabry (IOGS/X) | Dipolar Quantum Systems Group (Ferrier-Barbut/Lahaye, LCF) @ X
Summary:

Igor Ferrier-Barbut (CNRS DR, LCF/IOGS) works on dipolar and Rydberg quantum systems for quantum simulation. Research: (1) dipolar dysprosium (Dy) quantum gases — magnetic dipole-dipole interactions, supersolids, quantum droplets; (2) sub-wavelength structured atomic arrays as quantum simulation platforms; (3) collective light-matter interactions in dense cold-atom ensembles. Jacques Herbrand Grand Prize 2022. ERC Starting Grant (CORSAIR). Works in the Browaeys/Lahaye quantum optics group.

Department(s)/lab(s): Physics and Astronomy | Odom Research Group @ Northwestern
Summary:

The Odom Group studies trapped molecular ions at millikelvin temperatures using radio-frequency ion traps. Key directions: (1) Controlled preparation and single-quantum-state readout of trapped molecular ions (e.g., AlH⁺, SiO⁺, N₂⁺) — combining laser cooling, blackbody-radiation-assisted state preparation, and fluorescence detection for single-molecule precision spectroscopy; (2) Search for time-variation of fundamental constants (electron-to-proton mass ratio, fine structure constant α) using molecular vibrational/rotational transitions as highly sensitive probes; (3) Quantum effects in sub-Kelvin chemistry — probing tunneling, orbiting resonances, and quantum state control of reactive collisions between cold molecules. Member of CFP Northwestern.

Department(s)/lab(s): LKB / Physics, Sorbonne Université | Atom Chips Group (Reichel/LKB) @ ENS Paris
Summary:

Jakob Reichel (Professor, LKB Atom Chips) leads work on fiber Fabry-Perot microcavities for atom-light quantum interfaces and miniaturised sensors. Research: (1) fiber Fabry-Perot microcavities — sub-micron mirrors on fibre tips enabling strong single-atom coupling; integrated directly into atom chips; (2) TACC (Trapped Atom Clock on a Chip) — Rb atom clock with 5.8×10⁻¹³/√τ stability; ERC Advanced grant EQUEMI; (3) Sr optical-lattice cavity QED with quantum metrology; (4) MIREGA spinout — miniature portable greenhouse gas analyser combining FFP microcavities with telecom fibre optics for drone mounting; ERC Proof-of-Concept grant; (5) Rubidium CQED 'Sarocema' — individually addressable atom-tweezer array in fibre cavity for quantum simulation with long-range cavity-mediated interactions.

Department(s)/lab(s): Physics / Niels Bohr Institute | Quantum Metrology Group (Schäffer/Müller) @ UCPH
Summary:

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.

Department(s)/lab(s): QuTech / Applied Sciences | Taminiau Lab — NV Centers and Spin Quantum Networks (QuTech) @ TU Delft
Summary:

Tim Taminiau (QuTech team leader, Assoc Prof) develops NV-center quantum registers for sensing and quantum networks. Research: (1) NV-center nuclear spin registers — quantum control of up to 50 coupled 13C nuclear spins; (2) nanoscale NMR sensing — mapping external spin networks with sub-nm resolution; (3) silicon-carbide spin qubits — VSi centres for scalable quantum networks with fast entanglement rates; (4) quantum error correction in multi-spin diamond registers. NWO Vici Grant 2026. Quadrupolar nuclear spin spectroscopy of individual nuclei (Nano Letters 2024). Key for sensing proteins at nanoscale.

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

Christoph Westbrook co-heads the Quantum Gases group at LCF/IOGS. Research: (1) metastable helium (He*) BEC and ultracold atomic gases — atom optics, Bose-Hubbard physics, Anderson localization; (2) correlated atom pair production via four-wave mixing for quantum atom optics sensing; (3) atom laser and matter-wave interferometry. The group pioneered the He* BEC and uses correlated atom pairs for quantum sensing analogous to two-photon quantum optics.

Department(s)/lab(s): Physics / LKB | Ultracold Fermi Gases Group (Yefsah/LKB) @ ENS Paris
Summary:

Tarik Yefsah's group at LKB studies strongly interacting ultracold Fermi gases. Research: (1) Fermi gas mixtures — quantum simulation of condensed matter phenomena (BCS-BEC crossover, Fermi polaron); (2) quantum gas microscope experiments imaging individual atoms in optical lattices; (3) novel quantum phases in Fermi-Hubbard systems ('fermionic waltz' publication 2026). Relevant to quantum simulation and quantum gas-based sensing.