Sample-based calibration for cryogenic broadband microwave reflectometry measurements

TL;DR

This paper introduces a simple in situ calibration method for cryogenic broadband microwave reflectometry that uses the sample itself as a reference, improving measurement accuracy by minimizing environmental effects.

Contribution

The proposed Sample-Based Calibration (SBC) method allows for more accurate, environment-insensitive measurements by calibrating with the sample at known temperatures instead of external standards.

Findings

SBC provides the absolute impedance response of the sample.

SBC reduces environmental effects on measurements.

SBC enhances sensitivity at cryogenic temperatures.

Abstract

The characteristic frequencies of a system provide important information on the phenomena that govern its physical properties. In this framework, there has recently been renewed interest in cryogenic microwave characterization for condensed matter systems since it allows to probe energy scales of the order of a few $\mu$eV. However, broadband measurements of the absolute value of a sample response in this frequency range are extremely sensitive to its environment and require a careful calibration. In this paper, we present an \textit{in situ} calibration method for cryogenic broadband microwave reflectometry experiments that is both simple to implement and through which the effect of the sample electromagnetic environment can be minimized. The calibration references are here provided by the sample itself, at three reference temperatures where its impedance is assumed or measured, and not by external standards as is usual. We compare the frequency-dependent complex impedance (0.1--2 GHz) of an a-Nb$_{15}$Si$_{85}$ superconducting thin film obtained through this Sample-Based Calibration (SBC) and through an Open-Short-Load Standard Calibration (SC) when working at very low temperature (0.02--4 K) and show that the SBC allows us to obtain the absolute response of the sample. This method brings the calibration planes as close as possible to the sample, so that the environment electrodynamic response does not affect the measurement, provided it is temperature independent. This results in a heightened sensitivity, for a given experimental set--up.