Summary: One of Europe's largest and most productive AMO/quantum sensing groups. The QOLS group at the Blackett Laboratory (~15 academics, 30 postdocs, 50+ PhD students) spans cold matter (CCM: eEDM/YbF, atom interferometry for inertial/gravitational sensing), attoscience, quantum navigation, and biophotonics (FLIM, super-resolution). Imperial leads the AION consortium for atom interferometry (dark matter, gravitational waves). The Quantum Science and Device Facility (QSDF) and Blackett cleanroom support device work. Exceptionally strong for astro-oriented quantum sensing (AION, gravity gradiometry) and emerging biophotonics.
Notes: Top-10 global research university, ranked #2 in UK. The Department of Physics at the Blackett Laboratory hosts the Quantum Optics and Laser Science (QOLS) group — ~15 academic staff, 30 postdocs, 50+ PhD students — one of the largest AMO/quantum photonics groups in Europe. Key divisions: Centre for Cold Matter (CCM; eEDM/YbF, cold molecules, atom interferometry, quantum navigation), Laser Consortium (attoscience), Controlled Quantum Dynamics (theory), and Photonics Group (FLIM/super-resolution biophotonics). Imperial is lead institution of the AION consortium for atom interferometry. Has cleanroom facilities in the Blackett Building and a shared Quantum Science and Device Facility (QSDF). Cost of living in London is high (~£3,600/month). Very strong quantum technology ecosystem via QuEST and EPSRC Quantum Technology Hub.
Araujo is a long-standing leader of the LZ (LUX-ZEPLIN) liquid-xenon dark matter experiment at SURF, working on detector design, calibration and background rejection for direct-detection WIMP searches, and previously ZEPLIN. His group also contributes to future noble-liquid detector R&D.
Buchmueller is the lead PI of the AION consortium (~£10M funded by UKRI/STFC), leading Imperial's ultracold strontium lab developing single-photon large-momentum-transfer atom interferometry on the Sr clock transition. Key achievements: prototype Sr differential atom interferometer operating at the Standard Quantum Limit with laser noise rejection demonstrated (arXiv 2504.09158, Apr 2025); AION-10 technical design report published (Aug 2025). Buchmueller also leads the AEDGE space mission concept for the European Space Agency, seeking to deploy a km-scale Sr atom interferometer in space for dark matter and mid-frequency gravitational wave detection. Deeply involved in MAGIS-100 partnership (Fermilab) and Cold Atoms in Space community building with 130+ proponents. Active in CMS Collaboration at CERN.
Carr designs, builds and calibrates fluxgate magnetometers for planetary and heliophysics space missions (including ESA's JUICE and BepiColombo), covering everything from sensor electronics to in-flight calibration of magnetic-field instrumentation.
Clements studies dusty, infrared-luminous galaxies and gravitationally lensed submillimetre sources using Herschel, ALMA and other facilities to probe galaxy formation and evolution, and works on transient/anomaly detection in large astronomical surveys.
Cotter leads the Quantum Navigation research stream at Imperial's Centre for Cold Matter. He develops compact, fieldable cold-atom inertial sensors for GPS-denied navigation. Milestones: first demonstration of a cold-atom accelerometer on the London Underground (measuring acceleration/vibration in a real transit environment); successful field trials of quantum inertial sensors aboard the Royal Navy research ship XV Patrick Blackett (2023); Arctic field trials with Royal Navy (2025). His sensors use magnetically launched cold-atom Rb clouds and simultaneous multi-axis interferometry. He also contributes to AION-related atom interferometry work and the Quantum Technology Hub in Sensors and Timing. Department of Materials cross-appointment.
Devlin is a Royal Society URF at the Centre for Cold Matter building a new experiment to detect axion and dark matter particles. His prior work at CERN's BASE collaboration (Penning trap antiproton experiment) used the ultra-sensitive superconducting detection circuit of a cryogenic Penning trap to set new constraints on axion-like particle couplings to photons (~2.79 neV/c² range; PRL 2021). At Imperial he is developing a Penning trap single-photon counter concept using a single trapped electron to detect 30–60 GHz photons from axion-photon conversion in a strong magnetic field (arXiv 2601.05472, March 2026), targeting axion masses of 124–248 μeV. This approach could overcome the standard quantum noise limit that hampers conventional haloscope searches at high mass. Active PDRA posting open May 2025.
Dougherty was Principal Investigator for the Cassini magnetometer, which discovered evidence for a subsurface ocean at Enceladus, and now leads the magnetometer instrument for ESA's JUICE mission to the Jovian moons, combining spacecraft instrumentation with planetary magnetospheric science.
Dunsby co-invented oblique plane microscopy (a single-objective light-sheet technique) and develops multidimensional fluorescence lifetime and light-sheet imaging instrumentation for live-cell and tissue imaging, applied to cancer diagnostics and cell biology.
Edel's group develops nanopore- and nanogap-based single-molecule sensing platforms, combining nanofluidics, plasmonics and electrical/optical readout for ultrasensitive detection and sequencing of biomolecules.
French is Professor and former Head of the Photonics Group (2001–2013). His group at Imperial (with Dunsby and Neil) develops multidimensional fluorescence imaging technology for life sciences and clinical applications. Research portfolio: (1) FLIM — wide-field time-gated FLIM using gated optical intensifiers and TCSPC for single-cell FRET-based biosensing of protein-protein interactions, cell signalling (kinase activity), and drug-target engagement in multi-well plates; (2) Super-resolved microscopy — STED, easySTORM (lower-cost STORM), and SIM+FLIM for mapping molecular function to biological nanostructure below the diffraction limit; (3) FLIM endoscopy — flexible wide-field FLIM endoscopes for label-free cancer diagnostics (autofluorescence lifetime) and osteoarthritis cartilage; (4) Open-source imaging — automated multiwell plate FLIM reader for high-content drug screening. Satellite lab at Francis Crick Institute.