Hollenberg is the intellectual centre of gravity for diamond quantum sensing in Australia: a theorist-turned-programme-leader whose group develops NV-based quantum probes for biological systems and quantum-computing architectures in silicon and diamond. Current directions include the quantum-probe hyperspectral microscope, in which NV ensembles in a bulk diamond substrate report magnetic and spin-noise contrast from cells cultured directly on the surface; nanodiamond quantum probes for intracellular relaxometry and free-radical detection; theory of decoherence-based sensing (T1 relaxometry as a chemical-specificity channel rather than a nuisance); and single-cell magnetic resonance. He co-leads the Melbourne node of the ARC Centre of Excellence in Quantum Biotechnology (QUBIC) with Simpson and Hinde, which is explicitly chartered to build quantum sensors for live biology, including portable brain imagers. 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 his programme is one of the small number worldwide that has carried those ensemble protocols all the way into cell culture and tissue rather than stopping at proof-of-principle magnetometry. Preferred attribute present: the group's emphasis is on sensitivity and biological specificity rather than device fabrication, and QUBIC funding runs to 2030 with recurring postdoc recruitment.
Home leads the TIQI group working with Be+ and Ca+ trapped ions. Research directions: (1) Quantum error correction β fault-tolerant gates, surface code implementations with multi-ion chains; (2) Precision metrology β ytterbium ion optical clock, mixed-species ion chain spectroscopy and ytterbium HFS measurements; (3) Macroscopic superposition and quantum contextuality β creating nonclassical motional states in harmonic oscillators for tests of quantum foundations; (4) Scalable architectures β photonic integrated waveguides for individual ion addressing, quantum logic detection of spectroscopy ions. Key publications include first two-qubit gates with mixed species and records in quantum state readout fidelity. Lab is investigating quantum logic-enhanced spectroscopy of complex atomic systems.
Hong runs Hybrid Optical Quantum Technologies within Stuttgart's FMQ institute: optomechanical and opto-mechanical-spin hybrid devices used for quantum sensing and for tests of quantum mechanics at larger mass scales. Work covers cavity/phononic-crystal optomechanics driven toward the quantum regime (ground-state cooling, back-action-evading and quantum-limited displacement/force readout) and the coupling of diamond spin defects to mechanical motion, including levitated-diamond spin-mechanics -- where an NV inside a levitated particle both senses and controls the particle's motion. Relative to the established NV-ensemble quantum-sensing playbook (DEER, nanoscale NMR, T1 relaxometry at pT/sqrt(Hz) ensemble sensitivity), this is the same colour-centre physics, deliberately hybridized with mechanics: the sensing target shifts from magnetic field to force, acceleration and displacement, and the group sits alongside Wrachtrup's NV programme in the same building, which is a considerable practical advantage.
Hoogenboom leads a biophysics group at UCL specializing in high-speed atomic force microscopy. Research directions: (1) High-speed AFM β imaging conformational dynamics of DNA, proteins (including membrane channels), and chromatin at ms time resolution and sub-nm spatial resolution in aqueous conditions; (2) Nuclear pore complex β mapping transport selectivity and structure of NPCs in native nuclear envelopes using AFM; (3) Antimicrobial mechanisms β imaging membrane disruption by antimicrobial peptides in real time; (4) AFM-based force spectroscopy β measuring single-molecule interaction forces in chromatin and protein assemblies. Strong relevance to biological sensing at the single-molecule level.
The Hosseini Lab (Quantum Atom Optics) investigates lightβatom interactions in rare-earth crystals, room-temperature gases, and nanophotonic structures. Directions: (1) Quantum optical memories in TmΒ³βΊ:YAG and ErΒ³βΊ-doped solids using atomic frequency comb (AFC) and gradient echo memory (GEM) protocols for telecom-wavelength quantum networking; demonstrated efficient storage of multi-dimensional telecom photons (Optica Quantum 2025, Phys. Rev. Appl. 2025); (2) Cooperative/collective lightβmatter interactions in periodic rare-earth ion arrays in nano/micro-photonic structures (collaboration with Oak Ridge NL, Aydin group) for enhanced quantum memory coherence; (3) Quantum squeezed light β applied to enhanced thermoreflectance sensing of electronic hotspots (Appl. Phys. Lett. 2024); (4) Coherent levitation of macroscopic sensors (DARPA YFA 2024, $500k): magnetic and optical trapping of mm-scale objects as high-Q oscillators for magnetometry, vibrational sensing, accelerometry, inertial, and force sensing. Lab actively seeking postdocs in integrated photonics, quantum memory, and levitation sensing (2024β2025). ASEE Curtis W. McGraw Research Award 2026.
Hutzler's group uses cold and ultracold polar molecules (including polyatomics and laser-cooled species) as exquisitely sensitive probes of fundamental symmetry violation, searching for the electron electric dipole moment and other signatures of physics beyond the Standard Model; the group is developing molecules with enhanced sensitivity and internal co-magnetometry. For context, this complements the established paradigm of NV-diamond ensemble magnetometry (Hahn-echo/DEER, nanoscale NMR, T1 relaxometry) operating near pT/βHz sensitivity.
Irwin invented the transition-edge sensor (TES) and pioneered SQUID-multiplexed readout now used throughout CMB and dark-matter detector arrays; his group builds quantum-limited electromagnetic sensors for axion dark matter searches (DMRadio) and cryogenic calorimeters, pushing sensitivity to the standard quantum limit and beyond -- a field of quantum sensing that, like ensemble NV-diamond magnetometry reaching pT/βHz sensitivities, trades off bandwidth and volume for extreme field sensitivity.
Prof. Jacobsen's group develops novel methods, instruments, and analysis approaches for X-ray nanoscale imaging and applies them to biology and environmental science, using the Advanced Photon Source (APS) at Argonne. Directions: (1) Scanning X-ray fluorescence microscopy (SXFM) for organ-wide and nanoscale elemental mapping of metals (zinc, copper, iron) in biological tissues β central to the NIH-funded QE-Map national resource; imaging how metals regulate cellular functions, synaptic zinc signaling, and neurodegenerative disease; (2) X-ray ptychography and coherent diffractive imaging (CDI) for nanoscale biological imaging beyond the diffraction limit with improved dose efficiency; (3) Development of new algorithms, optics (zone plates), and detector systems to push spatial resolution and dose efficiency in X-ray microscopy β including lensless imaging methods and compressed-sensing reconstruction. Joint appointment at Argonne National Laboratory (Argonne Distinguished Fellow); also involved in QE-Map resource with Kozorovitskiy and Hao Zhang (McCormick).
Jacqmin works on chip-trapped ultracold-atom sources and matter-wave interferometry within LKB's Atom Chips team, part of the broader effort (alongside fiber Fabry-Perot microcavity work) to build compact, chip-scale atomic sensors and clocks.
Jacques is a pioneer of scanning NV magnetometry, using single nitrogen-vacancy spins in scanning-probe diamond tips to image magnetic textures at the nanoscale under ambient conditions. His team applies this to condensed-matter systems including antiferromagnetic domain walls and chiral spin textures, non-collinear antiferromagnetic order via single-spin relaxometry, and current-driven skyrmion motion in synthetic antiferromagnets, work carried out in close collaboration with materials-physics groups.