利用动态去耦操作多离子时钟

arXiv - PHYS - Atomic Physics Pub Date : 2024-08-09 DOI:arxiv-2408.05280

Nitzan Akerman, Roee Ozeri

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引用次数: 0

摘要

我们研究并描述了一种准连续动态解耦方案（QCDD），它能有效抑制多离子光时钟中的主要频移。为了应对这种系统中不均匀频移的挑战，我们的方案减轻了主要的频移因素，即电四极移动（QPS）和线性泽曼移动（LZS）。基于$^{88}$Sr$^+$离子，我们在多达 7 个离子的线性链中实施了 QCDD 方案，结果表明该方案显著抑制了三个数量级以上的频移，使相对频率不均匀性低于$7\cdot10^{-17}$。此外，我们还评估了 QCDD 方案中使用的射频（RF）驱动所产生的相关系统性偏移，结果表明，在所提出的实现方案中，射频驱动对系统相对频率不确定性的贡献低于 10^{-17}$ ，而且还有进一步提高的潜力。这些结果为实现多离子时钟提供了一条大有可为的途径，即在保持与单离子时钟类似的高精度的同时，将不稳定性提高一个数量级或更多。

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Operating a multi-ion clock with dynamical decoupling

We study and characterize a quasi-continuous dynamical decoupling (QCDD) scheme that effectively suppresses dominant frequency shifts in a multi-ion optical clock. Addressing the challenge of inhomogeneous frequency shifts in such systems, our scheme mitigates primary contributors, namely the electric quadrupole shift (QPS) and the linear Zeeman shift (LZS). Based on $^{88}$Sr$^+$ ions, we implement a QCDD scheme in linear chains of up to 7 ions and demonstrate a significant suppression of the shift by more than three orders of magnitude, leading to relative frequency inhomogeneity below $7\cdot10^{-17}$. Additionally, we evaluate the associated systematic shift arising from the radiofrequency (RF) drive used in the QCDD scheme, showing that, in the presented realization, its contribution to the systematic relative frequency uncertainty is below $10^{-17}$, with potential for further improvement. These results provide a promising avenue toward implementing multi-ion clocks exhibiting an order of magnitude or more improvement in stability while maintaining a similar high degree of accuracy to that of single-ion clocks.

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arXiv - PHYS - Atomic Physics

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