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Autores principales: Blodgett, Karl N., Phatak, Saumitra S., Chen, Meng Raymond, Peana, David, Pritts, Claire, Hood, Jonathan D.
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2505.10540
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author Blodgett, Karl N.
Phatak, Saumitra S.
Chen, Meng Raymond
Peana, David
Pritts, Claire
Hood, Jonathan D.
author_facet Blodgett, Karl N.
Phatak, Saumitra S.
Chen, Meng Raymond
Peana, David
Pritts, Claire
Hood, Jonathan D.
contents We demonstrate background-free imaging and sideband cooling of a single 133Cs atom via the narrow-line 6S1/2 to 5D5/2 electric quadrupole transition in a 1064 nm optical tweezer. The 5D5/2 state decays through the 6P3/2 state to the ground state, emitting an 852 nm wavelength photon that allows for background-free imaging. By encoding both spin and orbital angular momentum onto the 685 nm excitation light, we achieve background-free fluorescence histograms with 99.58(3)% fidelity by positioning the atom at the dark center of a vortex beam. Tuning the tweezer polarization ellipticity realizes a magic trap for the stretched F = 4, mF = 4 to F' = 6, mF' = 6 cycling transition. We cool to 5 uK in a 1.1 mK trap and outline a strategy for ground-state cooling. We compare cooling performance across different sideband regimes, while also exploring how the orbital angular momentum of structured light controls the selection rules for quadrupole transitions. These results expand the toolbox for high-fidelity quantum control and cooling in alkali-atom tweezer arrays.
format Preprint
id arxiv_https___arxiv_org_abs_2505_10540
institution arXiv
publishDate 2025
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spellingShingle Narrow-Line Electric Quadrupole Cooling And Background-Free Imaging Of A Single Cs Atom With Spatially Structured Light
Blodgett, Karl N.
Phatak, Saumitra S.
Chen, Meng Raymond
Peana, David
Pritts, Claire
Hood, Jonathan D.
Atomic Physics
Quantum Physics
We demonstrate background-free imaging and sideband cooling of a single 133Cs atom via the narrow-line 6S1/2 to 5D5/2 electric quadrupole transition in a 1064 nm optical tweezer. The 5D5/2 state decays through the 6P3/2 state to the ground state, emitting an 852 nm wavelength photon that allows for background-free imaging. By encoding both spin and orbital angular momentum onto the 685 nm excitation light, we achieve background-free fluorescence histograms with 99.58(3)% fidelity by positioning the atom at the dark center of a vortex beam. Tuning the tweezer polarization ellipticity realizes a magic trap for the stretched F = 4, mF = 4 to F' = 6, mF' = 6 cycling transition. We cool to 5 uK in a 1.1 mK trap and outline a strategy for ground-state cooling. We compare cooling performance across different sideband regimes, while also exploring how the orbital angular momentum of structured light controls the selection rules for quadrupole transitions. These results expand the toolbox for high-fidelity quantum control and cooling in alkali-atom tweezer arrays.
title Narrow-Line Electric Quadrupole Cooling And Background-Free Imaging Of A Single Cs Atom With Spatially Structured Light
topic Atomic Physics
Quantum Physics
url https://arxiv.org/abs/2505.10540