Optical coherent manipulation of alkaline-earth circular Rydberg states

Owing to their large size, Rydberg atoms are promising tools for quantum technologies 1 , 2 , as they exhibit long-range dipole–dipole interactions and strong coupling to external fields. Recent experiments have demonstrated their appeal for quantum simulation purposes 3 – 5 , even though the relati...

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Published in:Nature physics 2022-05, Vol.18 (5), p.502-505
Main Authors: Muni, Andrea, Lachaud, Léa, Couto, Angelo, Poirier, Michel, Teixeira, Raul Celistrino, Raimond, Jean-Michel, Brune, Michel, Gleyzes, Sébastien
Format: Article
Language:English
Subjects:
639/766/36/1121
639/766/483/3926
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Alkaline earth metals
Atomic
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Dipole interactions
Earth
Electrons
Letter
Mathematical and Computational Physics
Measurement techniques
Molecular
Optical activity
Optical and Plasma Physics
Optical pulses
Physics
Physics and Astronomy
Rydberg states
Strontium
Theoretical
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Summary:Owing to their large size, Rydberg atoms are promising tools for quantum technologies 1 , 2 , as they exhibit long-range dipole–dipole interactions and strong coupling to external fields. Recent experiments have demonstrated their appeal for quantum simulation purposes 3 – 5 , even though the relatively short lifetime of optically accessible Rydberg levels imposes limitations. Long-lived circular Rydberg states 6 , 7 may provide a solution. However, the detection of circular states involves either destructive 6 or complex 7 measurement techniques. Moreover, so far, alkali circular states have been manipulated only by microwave fields, which are unable to address individual atoms. The use of circular states of a different group of atoms, the alkaline-earth metals, which have an optically active second valence electron, can circumvent these problems. Here we show how to use the electrostatic coupling between the two valence electrons of strontium to coherently manipulate a circular Rydberg state with optical pulses. We also exploit this coupling to map the state of the Rydberg electron onto that of the ionic core. This experiment opens the way to a state-selective spatially resolved non-destructive detection of circular states and to the realization of a hybrid optical–microwave platform for quantum technology. The capabilities of optically accessible Rydberg levels are limited by their lifetime. An experiment demonstrates how to detect and manipulate long-lived circular states through the coupling of valence electrons in alkaline-earth Rydberg atoms.
ISSN:1745-2473
1745-2481
1476-4636
DOI:10.1038/s41567-022-01519-w