Works on quantum photonics and microwave-to-optical quantum transduction, collaborating on interconnects to link superconducting quantum processors via optical quantum networks.
Fejer develops engineered nonlinear-optical materials (periodically poled crystals, low-mechanical-loss optical coatings) used to generate squeezed light and to reduce thermal noise in precision interferometers, contributing core technology to the squeezed-light upgrades deployed in Advanced LIGO.
Igor Ferrier-Barbut (CNRS DR, LCF/IOGS) works on dipolar and Rydberg quantum systems for quantum simulation. Research: (1) dipolar dysprosium (Dy) quantum gases β 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.
Ivette Fuentes' group uses quantum information and metrology to probe fundamental physics at the interface of quantum theory and general relativity. Research: (1) quantum sensing of gravitational waves using relativistic quantum systems; (2) quantum clock synchronization and gravitational decoherence; (3) dark energy detection using quantum sensors; (4) quantum reference frames in curved spacetime. Bridges quantum sensing with gravitational physics.
Gangloff leads the Quantum Engineering Group at the Cavendish. Research spans three platforms: (1) Semiconductor quantum dots (InGaAs, GaAs) β demonstrating optical coherent control of quantum-dot nuclear spin ensembles (magnons, time crystals, many-body quantum registers); developing QD-based quantum repeater nodes (MEEDGARD QuantERA project); (2) Diamond group-IV spin defects (SiV, SnV, GeV) β precision positioning and high-purity single-photon generation from tin-vacancy centers; (3) Rydberg excitons in CuβO β exploring blockade-based optical quantum gates. The Integrated Quantum Networks Hub co-PI role underpins a broader quantum internet vision.
James Gates is a Professorial Fellow at Southampton's ORC, specialising in photonic fabrication for quantum technologies. Research: (1) low-loss glass waveguide fabrication for photonic quantum computing and sensing (EPSRC UPROAR and PURE projects); (2) fabrication innovations for superconducting and ion trap quantum computing; (3) atom trap photonic integration. PI of major EPSRC quantum technology grants; Co-I of QCS Hub and CDT in Quantum Technology Engineering. Key fabrication enabler for quantum photonic sensors.
The Geraci group employs high-Q resonant sensors for ultra-sensitive force and field detection in searches for new physics beyond the Standard Model. Key thrusts: (1) Optically-trapped levitated dielectric nanospheres and microspheres achieving zeptonewton (10β»Β²ΒΉ N) force sensitivity, applied to probing short-range deviations from Newtonian gravity at micrometer scales; (2) ARIADNE, an international NMR-based experiment using superfluid Β³He to search for the QCD axion via axion-mediated spin-dependent forces between a rotating mass and polarized nuclei; (3) Collaboration on MAGIS-100, the 100 m-tall atom interferometer at Fermilab for gravitational wave detection in the mid-band (0.3β10 Hz) and ultralight dark matter searches; (4) Cryogenic optical cavity dark matter comparisons with Gabrielse and Kovachy groups. Member of CFP Northwestern and CIERA. APS Francis M. Pipkin Award 2023.
Giessen works on ultrafast nano-optics and plasmonics, plasmonic and metasurface sensors, femtosecond two-photon 3D-printed micro-optics (on fiber tips and detectors), widely tunable ultrafast/mid-IR sources for molecular sensing, and Rydberg-exciton quantum optics in cuprous oxide. In the broader landscape of NV-centre ensemble quantum sensing (DEER, nano-NMR, T1 relaxometry) operating near pT/sqrt(Hz) sensitivity, this work sits adjacent as a nanophotonic sensing and light-source enabler.
Gigan leads the Optical Imaging group at LKB, pioneering wavefront shaping and computational imaging through scattering media. Research directions: (1) Wavefront shaping / transmission matrix β measuring the ~10^5 optical modes of a scattering sample's transmission matrix to focus and image through highly scattering biological tissues; roadmap on deep tissue imaging (J. Phys. Photonics 2022, lead author); (2) Multimode quantum optics through complex media β spatially multimode squeezed states transmitted through scattering media for quantum-enhanced imaging; (3) Optical computing / AI β using multiple scattering as a physical neural network for reservoir computing and nonlinear machine learning (LightOn spin-off, 2016); (4) Neurophotonics applications β focusing through the skull for deep brain imaging. Two ERC grants (2011, 2017). Optica Fellow. IUF member (2016β2021).
Sylvain Gigan's PICO (Photonics, Information, and Complexity) group focuses on imaging through and with complex and scattering media. Research: (1) wavefront shaping through scattering media β adaptive optics and transmission matrix approaches for deep-tissue fluorescence imaging; (2) multimode quantum optics through complex media β pushing quantum light through scattering and multi-mode fibres; (3) analogue computing with random optical scattering media. Key for biosensing: deep tissue imaging at high spatial resolution and quantum-enhanced light manipulation.