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Main Authors: Miyamoto, Masanari, Higuchi, Takashi, Furusawa, Kentaro, Sekine, Norihiko, Hayasaka, Kazuhiro, Tanaka, Utako
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.05002
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_version_ 1866915833503023104
author Miyamoto, Masanari
Higuchi, Takashi
Furusawa, Kentaro
Sekine, Norihiko
Hayasaka, Kazuhiro
Tanaka, Utako
author_facet Miyamoto, Masanari
Higuchi, Takashi
Furusawa, Kentaro
Sekine, Norihiko
Hayasaka, Kazuhiro
Tanaka, Utako
contents We developed a surface-electrode ion trap with a square hole measuring $40\,\mathrm{μm}$ for atomic loading. The hole was fabricated using anisotropic etching of a silicon substrate and was designed to minimize potential distortion in the trapping region. By introducing the atomic beam through the hole, we achieved enhanced isotope selectivity and experimentally demonstrated the selective trapping of calcium isotope ions using an atomic oven. We successfully prepared isotope ion pairs directly from the oven via sympathetic cooling at a rate comparable to that achieved using ablation loading. The sympathetic cooling process occurred on the order of a few seconds. We demonstrated the direct generation of an ion chain above the through-hole. This approach can be applied for trapping a wide range of ion species using a remarkably simple experimental setup, making it desirable for several applications such as quantum-charge-coupled-device (QCCD) architectures and precision measurements of isotope shifts.
format Preprint
id arxiv_https___arxiv_org_abs_2505_05002
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Isotope-selective Ion Trapping via Sympathetic Cooling using a Surface-Electrode Trap with a Hole for Collimated Atomic Loading
Miyamoto, Masanari
Higuchi, Takashi
Furusawa, Kentaro
Sekine, Norihiko
Hayasaka, Kazuhiro
Tanaka, Utako
Quantum Physics
Atomic Physics
We developed a surface-electrode ion trap with a square hole measuring $40\,\mathrm{μm}$ for atomic loading. The hole was fabricated using anisotropic etching of a silicon substrate and was designed to minimize potential distortion in the trapping region. By introducing the atomic beam through the hole, we achieved enhanced isotope selectivity and experimentally demonstrated the selective trapping of calcium isotope ions using an atomic oven. We successfully prepared isotope ion pairs directly from the oven via sympathetic cooling at a rate comparable to that achieved using ablation loading. The sympathetic cooling process occurred on the order of a few seconds. We demonstrated the direct generation of an ion chain above the through-hole. This approach can be applied for trapping a wide range of ion species using a remarkably simple experimental setup, making it desirable for several applications such as quantum-charge-coupled-device (QCCD) architectures and precision measurements of isotope shifts.
title Isotope-selective Ion Trapping via Sympathetic Cooling using a Surface-Electrode Trap with a Hole for Collimated Atomic Loading
topic Quantum Physics
Atomic Physics
url https://arxiv.org/abs/2505.05002