Narrowline cooling of dysprosium atoms in an optical tweezer array

Giulio Biagioni; Britton Hofer; Nathan Bonvalet; Damien Bloch; Antoine Browaeys; Igor Ferrier-Barbut

doi:10.1103/k4vn-y7mb

Narrowline cooling of dysprosium atoms in an optical tweezer array

Giulio Biagioni
, Britton Hofer
, Nathan Bonvalet
, Damien Bloch
, Antoine Browaeys
, Igor Ferrier-Barbut

Laboratoire Charles Fabry

Research output: Contribution to journal › Article › peer-review

Abstract

We perform narrowline cooling of single dysprosium atoms trapped in a one-dimensional optical tweezer array, employing the narrow single-photon transition at 741 nm. At the trapping wavelength of 532 nm, the excited state is less trapped than the ground state. To obtain efficient cooling performances, we chirp the frequency of the cooling beam to subsequently address the red sidebands of different motional states. We demonstrate the effectiveness of the cooling protocol through Raman thermometry, which we characterize for our experimental conditions. We obtain an array of 75 atoms close to the motional ground state in the radial direction of the tweezers. Our results demonstrate the possibility to manipulate the motional degree of freedom of dysprosium in optical tweezer arrays, a key ingredient to exploit the potential of lanthanide-based tweezer platforms for quantum science.

Original language	English
Article number	013316
Journal	Physical Review A
Volume	112
Issue number	1
DOIs	https://doi.org/10.1103/k4vn-y7mb
Publication status	Published - 25 Jul 2025
Externally published	Yes

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abstract = "We perform narrowline cooling of single dysprosium atoms trapped in a one-dimensional optical tweezer array, employing the narrow single-photon transition at 741 nm. At the trapping wavelength of 532 nm, the excited state is less trapped than the ground state. To obtain efficient cooling performances, we chirp the frequency of the cooling beam to subsequently address the red sidebands of different motional states. We demonstrate the effectiveness of the cooling protocol through Raman thermometry, which we characterize for our experimental conditions. We obtain an array of 75 atoms close to the motional ground state in the radial direction of the tweezers. Our results demonstrate the possibility to manipulate the motional degree of freedom of dysprosium in optical tweezer arrays, a key ingredient to exploit the potential of lanthanide-based tweezer platforms for quantum science.",

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T1 - Narrowline cooling of dysprosium atoms in an optical tweezer array

AU - Biagioni, Giulio

AU - Hofer, Britton

AU - Bonvalet, Nathan

AU - Bloch, Damien

AU - Browaeys, Antoine

AU - Ferrier-Barbut, Igor

PY - 2025/7/25

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N2 - We perform narrowline cooling of single dysprosium atoms trapped in a one-dimensional optical tweezer array, employing the narrow single-photon transition at 741 nm. At the trapping wavelength of 532 nm, the excited state is less trapped than the ground state. To obtain efficient cooling performances, we chirp the frequency of the cooling beam to subsequently address the red sidebands of different motional states. We demonstrate the effectiveness of the cooling protocol through Raman thermometry, which we characterize for our experimental conditions. We obtain an array of 75 atoms close to the motional ground state in the radial direction of the tweezers. Our results demonstrate the possibility to manipulate the motional degree of freedom of dysprosium in optical tweezer arrays, a key ingredient to exploit the potential of lanthanide-based tweezer platforms for quantum science.

AB - We perform narrowline cooling of single dysprosium atoms trapped in a one-dimensional optical tweezer array, employing the narrow single-photon transition at 741 nm. At the trapping wavelength of 532 nm, the excited state is less trapped than the ground state. To obtain efficient cooling performances, we chirp the frequency of the cooling beam to subsequently address the red sidebands of different motional states. We demonstrate the effectiveness of the cooling protocol through Raman thermometry, which we characterize for our experimental conditions. We obtain an array of 75 atoms close to the motional ground state in the radial direction of the tweezers. Our results demonstrate the possibility to manipulate the motional degree of freedom of dysprosium in optical tweezer arrays, a key ingredient to exploit the potential of lanthanide-based tweezer platforms for quantum science.

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Narrowline cooling of dysprosium atoms in an optical tweezer array

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