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Hauptverfasser: Ma, Shuo, Dolde, Jonathan, Zheng, Xin, Ganapathy, Dhruva, Shtov, Alexander, Chen, Jenny, Stoeltzel, Anke, Christensen, Bennett J., Kolkowitz, Shimon
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2505.06437
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author Ma, Shuo
Dolde, Jonathan
Zheng, Xin
Ganapathy, Dhruva
Shtov, Alexander
Chen, Jenny
Stoeltzel, Anke
Christensen, Bennett J.
Kolkowitz, Shimon
author_facet Ma, Shuo
Dolde, Jonathan
Zheng, Xin
Ganapathy, Dhruva
Shtov, Alexander
Chen, Jenny
Stoeltzel, Anke
Christensen, Bennett J.
Kolkowitz, Shimon
contents Increasing coherent interrogation times is central to advancing the precision of optical clocks. Synchronous differential optical clock comparisons have now demonstrated atomic coherence times that far exceed the coherence time of the clock laser. While atom coherence times are then primarily limited by errors induced by lattice Raman scattering, excited clock state radiative decay, and broadening from two-body collisions, many of these errors take the atoms out of the clock transition subspace, and can therefore be converted into "erasure" errors if the appropriate readout scheme is employed. Here we experimentally demonstrate a hyperfine-resolved readout technique for ${}^{87}$Sr optical lattice clocks that mitigates decoherence from Raman scattering induced by the lattice as well as radiative decay. By employing hyperfine-resolved readout in synchronous differential comparisons between ${}^{87}$Sr ensembles with both Ramsey and spin echo spectroscopy sequences, we achieve enhanced atomic coherence times exceeding 100 s and 150 s, respectively, enabling longer coherent measurements without a reduction in performance. We anticipate that this hyperfine-resolved readout technique will benefit applications of state-of-the-art optical lattice clock comparisons in which the coherence times are constrained by Raman scattering or radiative decay.
format Preprint
id arxiv_https___arxiv_org_abs_2505_06437
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhancing optical lattice clock coherence times with erasure conversion
Ma, Shuo
Dolde, Jonathan
Zheng, Xin
Ganapathy, Dhruva
Shtov, Alexander
Chen, Jenny
Stoeltzel, Anke
Christensen, Bennett J.
Kolkowitz, Shimon
Atomic Physics
Quantum Physics
Increasing coherent interrogation times is central to advancing the precision of optical clocks. Synchronous differential optical clock comparisons have now demonstrated atomic coherence times that far exceed the coherence time of the clock laser. While atom coherence times are then primarily limited by errors induced by lattice Raman scattering, excited clock state radiative decay, and broadening from two-body collisions, many of these errors take the atoms out of the clock transition subspace, and can therefore be converted into "erasure" errors if the appropriate readout scheme is employed. Here we experimentally demonstrate a hyperfine-resolved readout technique for ${}^{87}$Sr optical lattice clocks that mitigates decoherence from Raman scattering induced by the lattice as well as radiative decay. By employing hyperfine-resolved readout in synchronous differential comparisons between ${}^{87}$Sr ensembles with both Ramsey and spin echo spectroscopy sequences, we achieve enhanced atomic coherence times exceeding 100 s and 150 s, respectively, enabling longer coherent measurements without a reduction in performance. We anticipate that this hyperfine-resolved readout technique will benefit applications of state-of-the-art optical lattice clock comparisons in which the coherence times are constrained by Raman scattering or radiative decay.
title Enhancing optical lattice clock coherence times with erasure conversion
topic Atomic Physics
Quantum Physics
url https://arxiv.org/abs/2505.06437