PIs

Department(s)/lab(s): Institute of Physics (QUANTUM) | Quantenbit (AG Schmidt-Kaler) @ JGU
Summary:

Quantenbit operates segmented micro-structured Paul traps for scalable trapped-ion quantum information and, increasingly, for quantum sensing. Directions: (i) trapped Rydberg ions -- combining the tight confinement of a Paul trap with the giant polarizability of Rydberg states, which is simultaneously a fast-gate resource and an extremely sensitive electric-field probe; (ii) motional-mode sensing of electric fields and surface noise; (iii) deterministic single-ion implantation, where a cold ion is extracted from the trap and implanted with nm-scale placement -- directly relevant to building NV/donor arrays with known ion counts, and to single-ion detection validation; (iv) TACTICa, applying ion-trapping and quantum-logic spectroscopy to 229Th toward a nuclear clock; (v) single-atom heat engines and quantum thermodynamics. Relative to the established NV-ensemble quantum-sensing playbook (DEER, nanoscale NMR, T1 relaxometry at pT/sqrt(Hz) ensemble sensitivity), the deterministic-implantation line is the natural upstream complement: it is the route to engineering NV ensembles/arrays with controlled density rather than relying on stochastic implantation. Strong local coupling to Budker (Th-229, exotic physics) and Wendt (laser ionization).

Department(s)/lab(s): Physics (Cavendish Laboratory – AMOP Group) | Many-Body Quantum Dynamics Group @ Cambridge
Summary:

Schneider leads the Many-Body Quantum Dynamics group. His primary work is on optical lattice quantum simulation with ultracold atoms (quasicrystalline and kagome potentials, non-equilibrium dynamics), but he also co-leads a significant quantum sensing arm: he is a core Cambridge PI in the AION collaboration building a 10 m strontium single-photon atom interferometer at Oxford and contributing to MAGIS-100 at Fermilab, targeting mid-band gravitational wave detection and ultralight dark matter. In 2026 he co-leads the UKRI-funded SEQUIN project, a hybrid quantum-classical interferometer array combining atom interferometry with seismometers to probe gravitational waves and Earth's interior.

Department(s)/lab(s): Biology | Schnitzer Lab @ Stanford
Summary:

Schnitzer's lab invents miniaturized and fiber-based two-photon microscopes and voltage/calcium imaging methods that allow single-cell-resolution recording of neural activity in freely behaving animals, including recent wide-field fluorescence-lifetime voltage imaging developed with the Kasevich group for high-throughput readout of neuronal spiking.

Department(s)/lab(s): Chemistry | Scholes Group @ Princeton
Summary:

Scholes uses multidimensional ultrafast and coherence spectroscopies to probe wavepacket dynamics and quantum-mechanical phenomena in photosynthetic light-harvesting complexes, cavity QED, and photo-activated chemistry, including his group's resolution of a decade-long controversy over long-lived coherent coupling in the Fenna-Matthews-Olson complex. His current work extends coherence spectroscopy to quantum information science and photobiomodulation, squarely fitting the fundamental light-physics/quantum-optics side of the filter.

Department(s)/lab(s): School of Life Sciences (SV) | Schueder Lab (High-Resolution Microscopy) @ EPFL
Summary:

Schueder is a newly appointed (2025) EPFL Assistant Professor specializing in high-resolution microscopy and its biological applications. He played a key role in the development of DNA-PAINT, a super-resolution microscopy technique enabling nanometer-scale (~5 nm) visualization of cellular structures via transient programmable DNA hybridization. Research directions: (1) DNA-PAINT super-resolution β€” multiplexed, quantitative imaging of protein complexes in fixed and living cells with Exchange-PAINT; (2) Single-molecule localization below 5 nm resolution β€” resolving individual proteins within complexes; (3) Biological applications β€” imaging cytoskeletal networks, receptor clustering, chromatin organization; (4) Expanding to in situ structural biology β€” correlating super-resolution images with cryo-EM data. Transferred from ETH Zurich. Strong fit with EPFL imaging and structural biology ecosystem.

Department(s)/lab(s): Physics & Astronomy | Schuessler Laser Spectroscopy & Ion Trap Group @ TAMU
Summary:

Schuessler combines optical frequency combs with cavity-enhanced and mid-IR spectroscopy for ultrasensitive trace-gas and isotopic detection, and runs ion-trap precision mass/laser spectroscopy of exotic species. In the broader landscape of NV-centre ensemble quantum sensing (DEER, nano-NMR, T1 relaxometry) operating near pT/sqrt(Hz) sensitivity, this work is a comb-metrology counterpart to spin-based chemical sensing.

Department(s)/lab(s): Bioengineering | Schultz Neurotechnology Group @ Imperial
Summary:

Schultz uses two-photon calcium imaging and other optical neurotechnology to study neural population activity in vivo, with application to understanding circuit dysfunction in neurodegenerative disease and to brain-machine interfaces.

Techniques:
Department(s)/lab(s): Applied Physics | Schuster Lab @ Stanford
Summary:

A pioneer of circuit quantum electrodynamics, Schuster's group uses superconducting qubits and microwave resonators both as quantum-information platforms and as ultra-sensitive quantum-limited sensors/spectrometers, extending qubit-based readout to precision spectroscopy of otherwise inaccessible microwave-frequency phenomena.

Department(s)/lab(s): Applied Physics | Schwab Lab @ Caltech
Summary:

Schwab's group studies quantum limits of nanomechanical and electromechanical measurement, coupling mechanical resonators to superconducting circuits and qubits to explore back-action-evading measurement, ground-state control, and force/displacement sensing at the quantum limit. For context, this complements the established paradigm of NV-diamond ensemble magnetometry (Hahn-echo/DEER, nanoscale NMR, T1 relaxometry) operating near pT/√Hz sensitivity.

Department(s)/lab(s): Chemistry | Schwartz Lab (Single-Molecule Genomics) @ UWMadison
Summary:

Develops single-molecule genomics technologies using nanofluidics and optical mapping to analyze whole genomes and structural variation.