Landragin directs SYRTE and its Cold Atom Interferometry and Inertial Sensors team, which develops light-pulse atom interferometers as absolute gravimeters and gyroscopes: the Cold Atom Gravimeter (CAG), whose single-laser pyramid-reflector design he co-invented and commercialized through the start-up Muquans (now Absolute Quantum Gravimeter, AQG), and continuously-operating cold-atom gyroscopes reaching record joint sensitivity. Applications span geodesy, hydrology, volcano monitoring and inertial navigation. He received the CNRS Innovation Medal in 2020.
Lantz designs and characterizes the active seismic isolation and suspension control systems that let LIGO's kilometer-scale interferometers reach the sensitivities needed to detect gravitational waves, working on the classical-noise-suppression side of a fundamentally quantum-limited instrument.
Laucht works on the quantum control of spins across two platforms: donor spin qubits in silicon (with Morello and Dzurak), where he demonstrated electrically-driven single-spin control in a continuous microwave field and pioneered dressed-state protection against decoherence; and, more recently, spin defects in hexagonal boron nitride β a 2D material whose optically addressable spin defects are the most promising candidate for a van der Waals analogue of the NV centre, with the enormous advantage that the sensor can be placed a single atomic layer from the sample. Positioned against the established body of NV-ensemble quantum sensing work β DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity β hBN spin defects are the field's most active attempt to beat the standoff-distance limitation that caps near-surface NV ensemble sensitivity; a candidate with NV ODMR experience would be immediately productive here, running the same pulse sequences on a new defect. Strong fit.
Laurat leads the Quantum Networks team at LKB, developing quantum memories and atom-photon interfaces for quantum network applications. Research directions: (1) High-efficiency cold-atom quantum memories β DLCZ-protocol and AFC memories for telecom photons; demonstrating >90% efficiency and multimode operation; quantum cryptography integrating optical quantum memory (arXiv Mar 2025); (2) Waveguide QED β cold atoms coupled to nanofibers and nanophotonic waveguides for super-radiance, photon-bound states, and atom-photon gates; (3) Quantum network protocols β entanglement distribution, quantum repeater segments; part of European Quantum Flagship 'Quantum Internet Alliance'; (4) Hybrid entanglement β continuous-variable and discrete-variable hybrid entanglement for CHSH Bell tests (PRA 2024). Senior IUF member.
Julien Laurat's quantum networks group develops atomic interfaces for long-distance quantum communication and sensing. Research: (1) cold atom quantum memory using DLCZ-protocol and EIT β multi-mode storage, entanglement generation; (2) nanofibre-trapped atom light interface for quantum networks; (3) quantum memory for telecom-band photons using rare-earth crystals. CNRS Silver Medal 2026. ERC Consolidator grant. Highly relevant to quantum sensing via atomic sensors and quantum network nodes.
Lauret studies quantum light from low-dimensional materials - room-temperature single-photon emission from carbon nanotubes and defects in hexagonal boron nitride, coupled to photonic/plasmonic structures - a fundamental-photon and quantum-emitter platform. In the broader landscape of NV-centre ensemble quantum sensing (DEER, nano-NMR, T1 relaxometry) operating near pT/sqrt(Hz) sensitivity, this work provides solid-state single-photon sources adjacent to spin-defect sensing.
Le Jeannic works on heralded single-photon sources and atom-photon quantum-network interfaces at LKB, contributing to the hybrid quantum-network line led by Julien Laurat, with an emphasis on high-rate, high-fidelity photonic entanglement distribution.
Le Targat co-leads SYRTE's Optical Frequency Metrology team, which built and continuously operates two independent strontium optical lattice clocks alongside a mercury lattice clock, comparing them at the 10^-16 to 10^-17 level and to SYRTE's caesium fountain primary standards. This work underpins the prospective redefinition of the SI second on an optical transition and supports frequency-transfer, geodesy and fundamental-physics tests via fiber links to other French metrology laboratories.
Patrick Ledingham's Hybrid Quantum Networks Lab develops light-matter interfaces for large-scale quantum photonic networks. Research: (1) warm and cold atomic ensemble quantum memories (ORCA protocol in warm Rb vapour) for telecom-wavelength photon storage; (2) atom-photon entanglement generation; (3) multiplexed quantum memories for repeater nodes. Key for quantum sensing via atom-photon entanglement and quantum repeater architectures.
Lehnert's group develops quantum electromechanics and microwave-optical transduction, quantum-limited and squeezed microwave amplification (including TWPAs), and applies these tools to quantum networks and dark-matter searches, converting fragile quantum signals between microwave, mechanical, and optical domains. For context, this complements the established paradigm of NV-diamond ensemble magnetometry (Hahn-echo/DEER, nanoscale NMR, T1 relaxometry) operating near pT/βHz sensitivity.