We investigate the role of hyperfine structure in resonant-dipole interactions between two atoms cotrapped in an optical tweezer. Two-body loss rates from light-assisted collisions (LACs) are measured across the Rb87 hyperfine spectrum and connected to properties of molecular photoassociation potentials via a semiclassical model. To obtain our results, we introduce an imaging technique that leverages repulsive LACs to detect two atoms in a trap, thereby circumventing parity constraints in tweezers. Our findings offer key insights for exploiting hyperfine structure in laser-induced collisions to control cold atoms and molecules in a broad range of quantum science applications.
Quantifying Light-Assisted Collisions in Optical Tweezers across the Hyperfine Spectrum / Pampel, S. K.; Marinelli, M.; Brown, M. O.; D'Incao, J. P.; Regal, C. A.. - In: PHYSICAL REVIEW LETTERS. - ISSN 0031-9007. - 134:1(2025), pp. 013202.--013202.-. [10.1103/PhysRevLett.134.013202]
Quantifying Light-Assisted Collisions in Optical Tweezers across the Hyperfine Spectrum
Marinelli M.;
2025-01-01
Abstract
We investigate the role of hyperfine structure in resonant-dipole interactions between two atoms cotrapped in an optical tweezer. Two-body loss rates from light-assisted collisions (LACs) are measured across the Rb87 hyperfine spectrum and connected to properties of molecular photoassociation potentials via a semiclassical model. To obtain our results, we introduce an imaging technique that leverages repulsive LACs to detect two atoms in a trap, thereby circumventing parity constraints in tweezers. Our findings offer key insights for exploiting hyperfine structure in laser-induced collisions to control cold atoms and molecules in a broad range of quantum science applications.Pubblicazioni consigliate
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