Electromagnetically induced transparency based Rydberg-atom sensor for traceable voltage measurements

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY AVS quantum science Pub Date : 2022-09-01 DOI:10.1116/5.0097746
C. Holloway, N. Prajapati, J. Sherman, A. Rüfenacht, A. Artusio-Glimpse, M. Simons, Amy K. Robinson, D. L. La Mantia, E. Norrgard
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引用次数: 14

Abstract

We investigate the Stark shift in Rydberg rubidium atoms through electromagnetically induced transparency for the measurement of direct current (dc) and 60 Hz alternating current (ac) voltages. This technique has direct application to the calibration of voltage measurement instrumentation. We present experimental results for different atomic states that allow for dc and ac voltage measurements ranging from 0 to 12 V. While the state-of-the-art method for realizing the volt, the Josephson voltage standard, is significantly more accurate, the Rydberg atom-based method presented here has the potential to be a calibration standard with more favorable size, weight, power, and cost. We discuss the steps necessary to develop the Rydberg atom-based voltage measurement as a complementary method for dissemination of the voltage scale directly to the end user and discuss sources of uncertainties for these types of experiments.
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用于可追踪电压测量的基于电磁感应透明的里德伯原子传感器
我们通过电磁感应透明性研究了里德伯铷原子中的斯塔克位移,用于测量直流电(dc)和60 Hz交流电压。该技术直接应用于电压测量仪器的校准。我们给出了不同原子态的实验结果,允许从0到12的直流和交流电压测量 V.虽然实现伏特的最先进方法约瑟夫逊电压标准要精确得多,但本文提出的基于里德堡原子的方法有可能成为一种具有更有利尺寸、重量、功率和成本的校准标准。我们讨论了开发基于里德堡原子的电压测量所需的步骤,作为将电压标度直接传播给最终用户的补充方法,并讨论了这些类型实验的不确定性来源。
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9.90
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