Institutions

1 Nassau Hall
Princeton, NJ 08544
USA

Summary: Home to Bernien's neutral-atom quantum sensing/simulation lab and Romalis's spin-exchange-relaxation-free (SERF) magnetometers, among the most sensitive magnetic sensors in the world.

Notes: Small department, high per-capita PI quality; strong funding base from the Princeton Center for Complex Materials and DOE.

Warnings: Princeton town itself is small and car-dependent; nearest major city (Philadelphia/NYC) requires a train ride.

Department(s)/lab(s): Physics | Laboratory for Ultracold Quantum Gases (Bakr Lab) @ Princeton
Summary:

Bakr pioneered quantum gas microscopy, imaging individual atoms in Hubbard-regime optical lattices with single-site resolution to directly visualize charge, spin, and polaronic correlations in strongly correlated many-body systems, including recent work resolving itinerant spin polarons and the Nagaoka effect in triangular-lattice Hubbard systems. His single-particle/single-molecule-resolved imaging platforms are a borderline but relevant pivot into the quantum-sensing space via ultra-precise, quantum-limited detection of individual quantum particles; included here for review given the emphasis on cutting-edge spatial resolution rather than sensing per se.

Department(s)/lab(s): Physics | Princeton Axion Search (Chaudhuri Lab) @ Princeton
Summary:

Chaudhuri leads the Princeton Axion Search (PXS) and is a core contributor to the DMRadio program, using solenoidal lumped-element LC resonators, DC-SQUID and near-quantum-limited (traveling-wave parametric amplifier) readout to search for QCD axion dark matter from roughly neV to ueV masses; his group explicitly frames this as electromagnetic quantum sensing beyond the Standard Quantum Limit. He is actively developing superconducting resonators and RF quantum upconverters that push readout sensitivity toward and below the SQL.

Department(s)/lab(s): Physics | Cheuk Lab @ Princeton
Summary:

Cheuk laser-cools and traps individual laser-coolable molecules (e.g. CaF) in optical tweezer arrays, achieving high-fidelity non-destructive imaging, Raman sideband cooling, and on-demand entanglement of molecular qubits, with explicit applications to quantum simulation, quantum information processing, and quantum-enhanced sensing/precision measurement. The rich internal structure of molecules gives access to new sensing modalities (e.g. searches for new physics) that complement atom-based quantum sensors.

Department(s)/lab(s): Electrical and Computer Engineering | de Leon Lab @ Princeton
Summary:

The de Leon lab engineers nitrogen-vacancy and other color centers in diamond and wide-bandgap materials as solid-state quantum sensors and qubits, spanning materials growth and surface chemistry, nanophotonic integration, and magnetic-field/thermal sensing of quantum materials, alongside a parallel effort on superconducting qubit noise and loss. This builds on the broader tradition of ensemble NV magnetometry (DEER, NMR, T1 relaxometry) that has reached pT/sqrt(Hz)-class sensitivities, which de Leon's group extends toward single- and few-spin scanning-probe magnetometry of correlated electron materials.

Department(s)/lab(s): Physics | Galbiati Group (DarkSide) @ Princeton
Summary:

Galbiati co-leads the DarkSide/Global Argon Dark Matter Collaboration program (DarkSide-20k and successors), developing ultra-radiopure underground argon and cryogenic noble-liquid time-projection chambers for direct WIMP dark-matter detection, building on his earlier work on the Borexino solar-neutrino scintillator experiment. Included as a borderline quantum-sensing entry on the strength of the ultra-low-background, single-quantum (photon/ionization) detection technology his group has developed, which is now being adapted for other applications such as total-body PET imaging.

Department(s)/lab(s): Physics | Laboratory for the Physics of Life @ Princeton
Summary:

Gregor's Laboratory for the Physics of Life builds custom quantitative microscopes (single-objective oblique-plane light-sheet, multicolor live-imaging, single-molecule transcription imaging) to make precision, physics-style measurements of gene expression, morphogen gradients, and chromatin dynamics in living Drosophila embryos and mammalian gastruloids. He is actively recruiting PhD students and postdocs with expertise in super-resolution imaging, nonlinear/ultrafast optics, and instrumentation development.

Department(s)/lab(s): Physics | Jones CMB/SPIDER Group @ Princeton
Summary:

Jones leads the SPIDER balloon-borne CMB polarimeter (and the successor Taurus mission), building and flying large TES bolometer arrays from Antarctic long-duration balloon platforms to measure degree-scale CMB polarization with minimal atmospheric loading, and also leads SuperBIT, a near-diffraction-limited stratospheric optical telescope. Like Staggs, he is included here as an astronomy/instrumentation pivot whose science case rests on cutting-edge cryogenic detector-array sensitivity.

Department(s)/lab(s): Physics | Leifer Lab @ Princeton
Summary:

Leifer develops closed-loop optical instrumentation that simultaneously records brain-wide calcium activity and delivers single-neuron optogenetic perturbations in freely moving C. elegans, building functional atlases of signal propagation and studying how whole-brain neural dynamics generate behavior. His group's whole-brain, cellular-resolution imaging in unrestrained animals is a benchmark advanced-microscopy approach for linking neural dynamics to behavior.

Department(s)/lab(s): Physics | Romalis Group @ Princeton
Summary:

Romalis develops ultra-sensitive alkali-vapor magnetometers operating in the spin-exchange-relaxation-free (SERF) regime, K-noble-gas nuclear spin co-magnetometers used as gyroscopes and for electron/nuclear EDM and Lorentz-violation searches, and Rydberg-atom microwave electric-field sensors; his group's SERF magnetometers were the first used to detect brain magnetic fields. This continues and extends the historical arc of atomic and NV-ensemble quantum sensing (comparable in spirit to DEER/NMR/T1-relaxometry approaches reaching pT/sqrt(Hz) sensitivities), pushing scalar and vector magnetometry toward the fT/sqrt(Hz) and below regime through spin-squeezing and multi-pass optical cells.

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.