wanner - stark晶格时钟中2分钟的原子相干性和1.5×10−18在1s的不稳定性

IF 9 1区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Physical review letters Pub Date : 2025-09-03 DOI:10.1103/3wtv-sty2

Kyungtae Kim, Alexander Aeppli, William Warfield, Anjun Chu, Ana Maria Rey, and Jun Ye

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引用次数: 0

摘要

我们探索了87Sr光学晶格钟的原子相干性和测量精度的极限。我们对关键效应进行了详细的表征，包括晶格拉曼散射和浅晶格结构中的原子碰撞，确定了174(28)s 3𝑃0时钟状态寿命。在晶格深度和原子密度范围内的原子相干性研究揭示了与光子散射和原子相互作用相关的退相干机制。在降低的密度下，我们观察到相干时间为118(9)s，接近自发发射设定的基本极限。在这种相干性理解的指导下，我们证明了分数频率单位1秒时原子系综1.5×10−18的时钟不稳定性。我们的研究结果对于进一步推进光学晶格时钟在基础物理中的应用具有重要意义。

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Atomic Coherence of 2 Minutes and Instability of 1.5×10−18 at 1 s in a Wannier-Stark Lattice Clock

We explore the limits of atomic coherence and measurement precision in a 87 Sr optical lattice clock. We perform a detailed characterization of key effects, including lattice Raman scattering and atomic collisions in a shallow lattice configuration, determining a 174(28) s 3 𝑃0 clock state lifetime. Investigation of atomic coherence across a range of lattice depths and atomic densities reveals decoherence mechanisms related to photon scattering and atomic interaction. At a reduced density, we observe a coherence time of 118(9) s, approaching the fundamental limit set by spontaneous emission. Guided by this coherence understanding, we demonstrate a clock instability for an atomic ensemble of 1.5×10−18 at 1 s in fractional frequency units. Our results are important for further advancing the state of the art of an optical lattice clock for fundamental physics applications.

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来源期刊

Physical review letters 物理-物理：综合

CiteScore

16.50

自引率

7.00%

发文量

2673

审稿时长

2.2 months

期刊介绍： Physical review letters(PRL)covers the full range of applied, fundamental, and interdisciplinary physics research topics: General physics, including statistical and quantum mechanics and quantum information Gravitation, astrophysics, and cosmology Elementary particles and fields Nuclear physics Atomic, molecular, and optical physics Nonlinear dynamics, fluid dynamics, and classical optics Plasma and beam physics Condensed matter and materials physics Polymers, soft matter, biological, climate and interdisciplinary physics, including networks