Buechler leads quantum many-body theory at ITP III: strongly interacting quantum systems, quantum optics, and the theory of cold atomic and molecular gases -- in particular Rydberg systems, where he has been a central theorist for interaction-engineered tweezer arrays, dressed interactions and photon-photon interactions in Rydberg media. He is the theory counterpart to Pfau's and Wrachtrup's experiments in the same department. Relative to the established NV-ensemble quantum-sensing playbook (DEER, nanoscale NMR, T1 relaxometry at pT/sqrt(Hz) ensemble sensitivity), a theory-first inclusion: the relevant output is the protocol layer -- how to engineer Hamiltonians in interacting spin/Rydberg ensembles so that entanglement or dressing improves sensitivity beyond the standard quantum limit, which is exactly the theory an NV-ensemble sensing programme needs and rarely has in-house.
NON-PREFERRED (astronomy pivot, kept for review). Burdge discovers and characterizes compact binary systems (white dwarfs, neutron stars, black holes) using time-domain, multi-messenger methods, and develops ultrafast sub-electron-noise optical camera instrumentation (Lightspeed) for ground-based telescopes; this is a good fit for the 'sufficiently complicated sensor enabling temporal resolution' astro-pivot category rather than core quantum sensing.
Buscher leads optical/infrared astronomical interferometry research at the Cavendish, co-leading COAST and serving as System Architect for the Magdalena Ridge Observatory Interferometer (MROI) in New Mexico. Current work focuses on MROI science-combiner instrumentation, fringe tracking, and light source/alignment systems for the beam train. He also holds an EPSRC grant (with Haniff and Young) on machining metre-sized gratings with nanometre precision for ELT high-resolution spectrographs. He is President of the Scientific Council of the European Interferometry Initiative.
Bustamante is a founding figure of single-molecule biophysics, using optical and magnetic tweezers to measure the forces and torques generated by molecular motors (RNA polymerase, viral packaging motors, the ribosome) as they act on individual nucleoprotein complexes. The lab continues to push single-molecule force spectroscopy toward sub-piconewton, millisecond resolution to resolve mechanochemical intermediates invisible to bulk assays.
Byer's long-running program in nonlinear optics and laser physics has produced key technologies for precision measurement, including low-noise laser sources, optical materials, and interferometric techniques that underpin gravitational-wave detectors and frequency metrology.
Cai's group invented seqFISH/seqFISH+, a super-resolved single-molecule imaging technology that maps thousands of RNA, DNA and protein targets in situ with spatial context, enabling transcriptome- and genome-scale spatial genomics of tissues at single-molecule resolution. For context, this complements the established paradigm of NV-diamond ensemble magnetometry (Hahn-echo/DEER, nanoscale NMR, T1 relaxometry) operating near pT/âHz sensitivity.
Caldwell is a Royal Society University Research Fellow establishing the Molecular Quantum Matter Lab at UCL. Research directions: (1) Precision molecular spectroscopy for dark matter and fifth-force searches â measuring isotope shifts in molecular systems to test Standard Model predictions and probe new forces between neutrons and electrons; (2) Quantum control of molecules in external fields â laser cooling, Stark deceleration, and magneto-optical trapping of polar molecules; (3) Molecular beam spectroscopy with frequency comb referencing for ultra-high-precision lineshape measurements. The lab aims to build the most precise molecular spectrometer for BSM physics searches. Actively building the lab and seeking motivated students/postdocs.
Develops second- and third-harmonic generation (SHG/THG) nonlinear optical microscopy to image collagen and other non-centrosymmetric structural proteins label-free in tissue, with applications to cancer diagnosis and fibrosis, pushing spatial/orientational resolution of structural imaging in intact tissue.
PREFERRED. Cappellaro pioneered quantum magnetic sensing with electronic spin defects (NV centers) in diamond, and her group designs and controls solid-state spin qubit systems for quantum sensing, simulation, and quantum information processing, combining theoretical insight into spin dynamics with experimental control of dynamical decoupling and nuclear-spin registers for nanoscale NMR. This builds on the broader lineage of NV ensemble quantum sensing (DEER, NMR, T1 relaxometry) that has pushed AC/DC magnetic sensitivities toward the pT/sqrt(Hz) regime, which her group's Hamiltonian-engineering and nuclear-spin-register approaches aim to extend further.
Experimental cosmologist building and operating CMB telescopes. Directions: (1) South Pole Telescope â PI of SPT series; SPT-3G currently mapping CMB temperature and polarization at arcminute resolution; (2) thermal and kinematic Sunyaev-Zel'dovich effect mapping for galaxy cluster cosmology; (3) CMB gravitational lensing for large-scale structure; (4) CMB-S4 design and planning. Argonne joint appointment. APS and AAAS Fellow.