具有混合物种晶体的超精细陷阱离子中三足鼎立结构的电磁诱导透明冷却

arXiv - PHYS - Atomic Physics Pub Date : 2024-08-23 DOI:arxiv-2408.13407

J. J. Wu, P. -Y. Hou, S. D. Erickson, A. D. Brandt, Y. Wan, G. Zarantonello, D. C. Cole, A. C. Wilson, D. H. Slichter, D. Leibfried

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引用次数: 0

摘要

原子运动冷却是原子物理学许多分支的重要工具，从基础物理学探索到量子信息和传感。对于被困离子，电磁诱导透明（EIT）冷却技术因其相对速度快、激光功率要求低和冷却带宽宽而受到关注。然而，在用于冷却的离子具有超精细结构以实现较长相干时间的应用中，很难找到一个封闭的三电平系统来执行标准的 EIT 冷却。在这里，我们通过增加一个额外的激光频率，成功地演示了 25Mg+ 的 EIT 冷却；这种方法可以应用于任何核自旋不为零的离子。此外，我们还演示了通过 25Mg+ 离子同时对混合物种晶体 9Be+ -25Mg+ 和 9Be+ - 25Mg+ - 9Be+ 中的所有轴向模式进行 EIT 冷却。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Electromagnetically-Induced-Transparency Cooling with a Tripod Structure in a Hyperfine Trapped Ion with Mixed-Species Crystals

Cooling of atomic motion is a crucial tool for many branches of atomic physics, ranging from fundamental physics explorations to quantum information and sensing. For trapped ions, electromagnetically-induced-transparency (EIT) cooling has received attention for the relative speed, low laser power requirements, and broad cooling bandwidth of the technique. However, in applications where the ion used for cooling has hyperfine structure to enable long coherence times, it is difficult to find a closed three-level system in which to perform standard EIT cooling. Here, we demonstrate successful EIT cooling on 25Mg+ by the addition of an extra laser frequency; this method can be applied to any ion with non-zero nuclear spin. Furthermore, we demonstrate simultaneous EIT cooling of all axial modes in mixed-species crystals 9Be+ - 25Mg+ and 9Be+ - 25Mg+ - 9Be+ through the 25Mg+ ion.

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arXiv - PHYS - Atomic Physics

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