Bonsor studies the composition and evolution of exoplanetary systems through the spectra of polluted white dwarfs, whose atmospheres reveal the bulk geochemistry of accreted asteroids and comets, providing a unique observational window into planet formation and the delivery of prebiotic material.
Booth's Dynamic Optics and Photonics Group develops adaptive-optics methods (deformable mirrors, spatial light modulators) for aberration correction in confocal, two-photon and super-resolution (STORM/STED/SIM) microscopy, enabling higher-fidelity deep-tissue biomedical imaging, alongside applications in ultrafast laser micro-fabrication of photonic devices.
Develops novel optical biomedical imaging technologies (OCT, nonlinear/multiphoton microscopy) for cancer detection, primary-care diagnostics, and neurophotonics, and translates them toward clinical and commercial application.
Bose originated (with Marletto and Vedral) the Bose-Marletto-Vedral (BMV) proposal to witness whether gravity is fundamentally quantum, by testing for gravitationally-induced entanglement between two spatially superposed masses using matter-wave (Stern-Gerlach) interferometry -- an idea he co-developed with quantum-sensing experimentalists including Andrew Geraci (Northwestern) and Peter Barker (UCL). He continues to develop the theory of these quantum-gravity-induced entanglement of masses (QGEM) tests, including decoherence mitigation and multi-qubit witnessing schemes, positioning nanocrystal/levitated-mass interferometry as a route to laboratory tests of quantum gravity.
Boskovic is a synthetic inorganic chemist working on lanthanoid and polyoxometalate molecular magnets, valence tautomeric and redox-switchable complexes, and the design of molecules whose spin states can be addressed and switched. The group's relevance to quantum sensing is that these are chemically tunable spin qubits: unlike solid-state defects, their coordination environment, nuclear-spin bath and anisotropy can be designed atom by atom, which is the argument for molecular qubits as sensors. Characterisation is by SQUID magnetometry, EPR and ab initio calculation. Positioned against the established body of NV-ensemble quantum sensing work — DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity — molecular spin qubits are the chemistry community's answer to the NV centre, and DEER/pulsed-EPR protocols developed for NV ensembles at pT/sqrt(Hz) transfer more or less directly to these systems. Borderline inclusion (synthesis-led rather than sensitivity-led), kept per the inclusive rubric.
Bottom builds high-contrast coronagraphic instruments and adaptive-optics systems for direct imaging and characterization of exoplanets, including infrared detector and instrument-concept development for the Habitable Worlds Observatory. The group is actively recruiting postdocs interested in astronomical instrumentation.
Boudot has been a permanent CNRS researcher in the Time-Frequency department of FEMTO-ST since 2008, developing compact and miniaturized atomic clocks based on coherent population trapping (CPT) in cesium vapor microcells, including all-optical, cavity-free designs that remove the traditional microwave cavity to shrink clock volume toward chip scale for GNSS, telecom and potential deep-sea seismic-sensing deployment. He received the EFTF Young Scientist Award in 2020 for this work.
Bowen leads the CQSE 'Spins and Qubits' theme at Manchester, focusing on organometallic molecular spin qubits for quantum sensing and computing. Research directions: (1) Organometallic La(II) and other rare-earth molecular qudits — designing molecules with multiple accessible spin states (qudits) for encoding quantum information and sensing; (2) Pulsed EPR characterization — Hahn echo, ESEEM, ENDOR at X/W/Q-band to measure coherence times and hyperfine couplings; (3) Integration of molecular qubits into devices — surface deposition and nanoscale addressing; (4) Multi-spin sensing — using exchange-coupled spin pairs as differential sensors of magnetic field gradients. Closely collaborates with Tuna and Winpenny.
Boxer's group uses vibrational Stark effect spectroscopy -- measuring field-dependent shifts of nitrile, carbonyl, and other IR-active vibrational probes -- to quantify electrostatic fields inside proteins, membranes, and active sites, providing a molecular-scale, spectroscopic route to electric-field sensing distinct from device-based quantum sensors. [Borderline match: a molecular spectroscopic probe of local fields rather than a fabricated quantum sensor; kept for review.]
PREFERRED. Boyden co-invented optogenetics and expansion microscopy, the latter physically swelling fixed tissue in a hydrogel to achieve nanoscale-resolution imaging on conventional diffraction-limited microscopes; his Synthetic Neurobiology Group continues to push these techniques (expansion revealing, thousandfold expansion microscopy) alongside genetically encoded voltage/activity indicators and brain-wide circuit mapping. The group's Media Lab page notes it is currently accepting new students.