An analysis method for transmission measurements of superconducting resonators with applications to quantum-regime dielectric-loss measurements

TL;DR

This paper introduces a comprehensive analysis method for superconducting resonator transmission measurements, enabling precise determination of internal quality factors and energy relations, applicable to various resonator types in quantum dielectric-loss studies.

Contribution

It presents the Closest Pole and Zero Method (CPZM), a systematic approach for analyzing high-Q resonator responses, including effects of impedance mismatch and non-idealities.

Findings

Reliable extraction of internal quality factor from transmission data.

Self-consistent calculation of voltage-energy relation in resonators.

Robustness of the method in non-ideal measurement conditions.

Abstract

Superconducting resonators provide a convenient way to measure loss tangents of various dielectrics at low temperature. For the purpose of examining the microscopic loss mechanisms in dielectrics, precise measurements of the internal quality factor at different values of energy stored in the resonators are required. Here, we present a consistent method to analyze a LC superconducting resonator coupled to a transmission line. We first derive an approximate expression for the transmission S-parameter $S_{21}$ based on a complete circuit model. In the weak coupling limit, we show that the internal quality factor is reliably determined by fitting the approximate form of $S_{21}$. Since the voltage $V$ of the capacitor of the LC circuit is required to determine the energy stored in the resonator, we next calculate the relation between $V$ and the forward propagating wave voltage $V_{in}^+$. Due to the dependence of the quality factor on voltage, $V$ is not simply proportional to $V_{in}^+$. We find a self-consistent way to determine the relation between $V$ and $V_{in}^+$, which employs only the fitting parameters for $S_{21}$ and a linear scaling factor. We then examine the resonator transmission in the cases of port reflection and impedance mismatch. We find that resonator transmission asymmetry is primarily due to the reflection from discontinuity in transmission lines. We show that our analysis method to extract the internal quality factor is robust in the non-ideal cases above. Finally, we show that the analysis method on LC resonator can be generalize to arbitrary weakly coupled lumped and distributed resonators. The generalization uses a systematic approximation on the response function based on the pole and zero which are the closest to the resonance frequency. This Closest Pole and Zero Method (CPZM) is a valuable tool for analyzing physical measurements of high-Q resonators.