Revisiting collisional broadening of $^{85}$Rb Rydberg levels: conclusions for vapor cell manufacture

arXiv - PHYS - Atomic Physics Pub Date : 2024-08-29 DOI:arxiv-2408.16669

Mingxin Lei, Stephen P. Eckel, Eric B. Norrgard, Nikunjkumar Prajapati, Alexandra B. Artusio-Glimpse, Matthew T. Simons, Christopher L. Holloway

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Abstract

Electrometry based on electromagnetically induced transparency (EIT) in alkali Rydberg vapor cells may suffer reduced sensitivity due to spurious line broadening effects, caused by surface charges, contaminant gases, or other manufacturing defects. In order to draw conclusions about the deleterious effects of potential contaminant gases inside Rydberg electrometry vapor cells, we revisit collisional broadening and shifts of both the D$_2$ line and Rydberg levels of rubidium. Specifically, we measure the broadening and shifts of the $5{\rm S}_{1/2}\rightarrow 5{\rm P}_{3/2}$ (i.e., the D$_2$ line) and $5{\rm S}_{1/2}\rightarrow 5{\rm P}_{3/2}\rightarrow (25{\rm D},27{\rm S},30{\rm D},32{\rm S},35{\rm D},37{\rm S})$ transitions of $^{85}$Rb due to He, Ne, N$_2$ and Ar. By combining these measurements with observations of velocity changing collisions in the sub-Doppler spectrum of the D$_2$ line, we conclude the following: (1) that contaminant gases are most likely not the cause of irregular line shapes or shifts of Rydberg transitions due to the high pressures required, and (2) the sub-Doppler spectrum of the D$_2$ line, through its accompanying loss of contrast at high pressures, can validate that a vapor cell is sufficiently free of contaminant gas for EIT electrometry. We use the theory of Omont, J. Phys. France 38, 1343 (1977), to extend our results to a wide variety of possible contaminant gases and further derive scaling laws applicable to all gases.

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重新审视 $^{85}$Rb Rydberg 水平的碰撞展宽：汽化电池制造的结论

由于表面电荷、污染气体或其他制造缺陷造成的虚假线宽效应，碱雷德贝格蒸气电池中基于电磁诱导透明（EIT）的电测量法可能会降低灵敏度。为了就雷德贝格电测量汽相池内潜在的污染气体的去耦效应得出结论，我们重新研究了铷的 D$_2$ 线和雷德贝格电平的碰撞展宽和位移。具体来说，我们测量了$5{rm S}_{1/2}/rightrow 5{\rm P}_{3/2}$（即、(25{\rm D},27{\rm S},30{\rmD},32{\rm S},35{\rm D},37{\rm S})$ Transition of $^{85}$Rb due to He, Ne, N$_2$ and Ar.通过将这些测量结果与 D$_2$ 线的亚多普勒频谱中的速度变化碰撞观测结果相结合，我们得出了以下结论：(1) 由于所需的高压，污染气体很可能不是造成不规则线形或雷德贝格跃迁位移的原因；(2) D$_2$ 线的亚多普勒频谱，通过其在高压下伴随的对比度损失，可以验证蒸发池中是否充分不含污染气体，以进行 EIT 电测量。我们使用 Omont 的理论，J. Phys. France 38, 1343 (1977)，将我们的结果扩展到各种可能的污染气体，并进一步推导出适用于所有气体的比例定律。

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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