Observation of Asymmetric Sideband Generation in Strongly-driven Rydberg Atoms

arXiv - PHYS - Atomic Physics Pub Date : 2024-08-20 DOI:arxiv-2408.10989

Dangka Shylla, Nikunjkumar Prajapati, Andrew P. Rotunno, Noah Schlossberger, Dixith Manchaiah, William J. Watterson, Alexandra Artusio-Glimpse, Samuel Berweger, Matthew T. Simons, Christopher L. Holloway

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Abstract

Improving the bandwidth of Rydberg atom-based receivers is an ongoing challenge owing to the long-lived Rydberg state lifetimes that limit the refresh rate of ground state atoms. In particular, the LO-based Rydberg mixer approach allows for bandwidths into the few-MHz range. Here, we use heterodyne detection of the Rydberg atom receiver probe laser to separate the negative and positive sidebands that originate from distinct six wave mixing processes, in order to investigate their individual bandwidths. We experimentally confirm the prediction that the negative sideband exhibits a higher bandwidth than the positive sideband. We further explore the effect of coupling and probe laser Rabi frequency on the bandwidth, which we find to be in good agreement with our model. We achieved a maximum experimental (and theoretical) bandwidth of about 11 (11) MHz and 3.5 (5) MHz for the negative and positive sidebands, respectively, from the -3dB roll-off point for optimized field parameters. This work provides insight into the bandwidth-limiting features of Rydberg atom receivers and points the way towards further optimization of their response.

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观测强驱动里德伯原子中的不对称边带生成

提高基于雷德贝格原子的接收器的带宽是一个持续的挑战，这是因为长寿命的雷德贝格状态寿命限制了基态原子的刷新率。特别是，基于 LO 的 Rydberg 混频器方法允许带宽达到几兆赫范围。在这里，我们利用雷德贝格原子接收探针激光的异调探测来分离源于不同六波混合过程的负边带和正边带，从而研究它们各自的带宽。我们通过实验证实了负边带的带宽高于正边带的预测。我们进一步探讨了耦合和探针激光拉比频率对带宽的影响，结果发现与我们的模型十分吻合。在优化场参数的情况下，从-3dB 滚降点算起，负边带和正边带的最大实验（和理论）带宽分别约为 11 (11) MHz 和 3.5 (5) MHz。这项研究深入揭示了雷德堡原子接收器的带宽限制特性，并为进一步优化其响应指明了方向。

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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arXiv - PHYS - Atomic Physics

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