Numerical model of N-level cascade systems for atomic Radio Frequency sensing applications

IF 5.8 2区物理与天体物理 Q1 OPTICS

EPJ Quantum Technology Pub Date : 2024-11-18 DOI:10.1140/epjqt/s40507-024-00291-5

Liam W. Bussey, Yogeshwar B. Kale, Samuel Winter, Fraser A. Burton, Yu-Hung Lien, Kai Bongs, Costas Constantinou

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引用次数: 0

Abstract

A ready-to-use numerical model has been developed for the atomic ladder (cascade) systems which are widely exploited in Rydberg Radio Frequency (RF) sensors. The model has been explicitly designed for user convenience and to be extensible to arbitrary N-level non-thermal systems. The versatility and adaptability of the model is validated up to 4-level atomic systems by direct comparison with experimental results from the prior art. The numerical model provides a good approximation to the experimental results and provides experimentalists with a convenient ready-to-use model to optimise the operation of an N-level Rydberg RF sensor. Current sensors exploit the 4-level atomic systems based on alkali metal atoms which require visible frequency lasers and these can be expensive and also suffer from high attenuation within optical fiber. The ability to quickly and simply explore more complex N-level systems offers the potential to use cheaper and lower-loss near-infrared lasers.

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用于原子射频传感应用的 N 级级联系统数值模型

针对雷德贝格射频（RF）传感器中广泛使用的原子阶梯（级联）系统，我们开发了一种即用型数值模型。该模型设计明确，方便用户使用，并可扩展到任意 N 级非热系统。通过与现有技术的实验结果进行直接比较，该模型的多功能性和适应性得到了验证，最高可达 4 级原子系统。该数值模型提供了与实验结果的良好近似，并为实验人员提供了方便的即用模型，以优化 N 级雷德堡射频传感器的运行。目前的传感器利用基于碱金属原子的 4 级原子系统，这种系统需要可见光频率的激光器，而这些激光器价格昂贵，在光纤中还会出现高衰减。能够快速、简单地探索更复杂的 N 级系统，为使用更便宜、损耗更低的近红外激光器提供了可能。

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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来源期刊

EPJ Quantum Technology Physics and Astronomy-Atomic and Molecular Physics, and Optics

CiteScore

7.70

自引率

7.50%

发文量

审稿时长

71 days

期刊介绍： Driven by advances in technology and experimental capability, the last decade has seen the emergence of quantum technology: a new praxis for controlling the quantum world. It is now possible to engineer complex, multi-component systems that merge the once distinct fields of quantum optics and condensed matter physics. EPJ Quantum Technology covers theoretical and experimental advances in subjects including but not limited to the following: Quantum measurement, metrology and lithography Quantum complex systems, networks and cellular automata Quantum electromechanical systems Quantum optomechanical systems Quantum machines, engineering and nanorobotics Quantum control theory Quantum information, communication and computation Quantum thermodynamics Quantum metamaterials The effect of Casimir forces on micro- and nano-electromechanical systems Quantum biology Quantum sensing Hybrid quantum systems Quantum simulations.