Quantum and nonlinear effects in light transmitted through planar atomic arrays

Quantum and nonlinear effects in light transmitted through planar atomic arrays

Understanding strong cooperative optical responses in dense and cold atomic ensembles is vital for fundamental science and emerging quantum technologies. Methodologies for characterizing light-induced quantum effects in such systems, however, are still lacking. Here we unambiguously identify signifi...

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Bibliographic Details
Published in:Communications physics Vol. 3; no. 1
Main Authors: Bettles, Robert J., Lee, Mark D., Gardiner, Simon A., Ruostekoski, Janne
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 14-08-2020
Nature Publishing Group
Subjects:
639/624/400/482
639/766/483
Arrays
Computer simulation
Dipole interactions
Disks
Entanglement
Light
Light transmission
Luminous intensity
Physics
Physics and Astronomy
Robustness (mathematics)
Splitting
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Summary:Understanding strong cooperative optical responses in dense and cold atomic ensembles is vital for fundamental science and emerging quantum technologies. Methodologies for characterizing light-induced quantum effects in such systems, however, are still lacking. Here we unambiguously identify significant quantum many-body effects, robust to position fluctuations and strong dipole–dipole interactions, in light scattered from planar atomic ensembles by comparing full quantum simulations with a semiclassical model neglecting quantum fluctuations. We find pronounced quantum effects at high atomic densities, light close to saturation intensity, and around subradiant resonances. Such conditions also maximize spin–spin correlations and entanglement between atoms, revealing the microscopic origin of light-induced quantum effects. In several regimes of interest, our approximate model reproduces light transmission remarkably well, permitting analysis of otherwise numerically inaccessible large ensembles, in which we observe many-body analogues of resonance power broadening, vacuum Rabi splitting, and significant suppression in cooperative reflection from atomic arrays. Many-body formalism for light transmission is developed to identify light-induced quantum effects and entanglement in atomic planar arrays and disks. Outside the regimes of pronounced quantum effects, potent semiclassical models reveal many-body analogues of power broadening and vacuum Rabi splitting.
ISSN:2399-3650
2399-3650
DOI:10.1038/s42005-020-00404-3