Simulation and Measurement of the Vacuum Rabi Coupling g in a 3D Transmon System

2019 IEEE International Superconductive Electronics Conference (ISEC) Pub Date : 2019-07-01 DOI:10.1109/ISEC46533.2019.8990932

J. Son., Soon-Gul Lee, Woon Song, Y. Chong, Gahyun Choi, T. Noh, Jisoo Choi, Gwanyeol Park, Joonyoung Lee, B. Kang, Kibog Park, Kwan-Woo Lee

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Abstract

A transmon qubit in the 3-dimensional microwave cavity is a versatile system for various circuit QED experiments. We have performed numerical calculations of the vacuum Rabi coupling $g$ in 3D transmon circuit QED system, and compared the values with the experimental measurements. We used COMSOL Multiphysics RF package with an appropriate model to efficiently calculate the coupling strength. The calculation agrees with the measurement within a few percents in simple cases. Depending on the position of the qubit in the cavity, we calculated the coupling strengths to different eigenmodes. We compared our result for the fundamental mode (TE101) and a higher mode (TE201) with the experiment by changing the qubit position, as shown in Fig. 2. This simulation and characterization enable efficient design methods for future 3D circuit QED experiments. We confirm that we can design and predict the qubit coupling to the cavity modes with enough accuracy in 3D circuit QED system.

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三维传输系统真空拉比耦合的仿真与测量

三维微波腔中的transmon量子位元是各种电路QED实验的通用系统。本文对三维透射电路QED系统中的真空拉比耦合进行了数值计算，并与实验测量值进行了比较。采用COMSOL Multiphysics RF封装，建立合适的模型，有效地计算了耦合强度。在一些简单的情况下，计算结果与测量结果在几个百分点的范围内吻合。根据量子比特在腔中的位置，我们计算了不同特征模的耦合强度。通过改变量子比特的位置，我们将基模(TE101)和高模(TE201)的结果与实验进行了比较，如图2所示。这种模拟和表征为未来的3D电路QED实验提供了有效的设计方法。我们证实了在三维电路QED系统中，我们能够以足够的精度设计和预测量子比特与腔模式的耦合。

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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2019 IEEE International Superconductive Electronics Conference (ISEC)

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