Description: Confines and further cools individual polyatomic or diatomic molecules held in optical tweezers to study state-controlled ultracold chemical reactions and molecule-based quantum information.
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.
Ni's group creates and controls individual molecules at the lowest achievable temperatures, using optical tweezers to study state-resolved ultracold chemical reactions and quantum effects in molecular collisions. Included here as a borderline precision-measurement/quantum-sensing platform (ultracold polar molecules), analogous to the eEDM/ultracold-molecule work elsewhere in the department, though her core emphasis is chemical reaction dynamics rather than device sensing.