Microwave resonator for measuring time-reversal symmetry breaking at cryogenic temperatures

TL;DR

This paper introduces a microwave resonator method to detect time-reversal symmetry breaking in unconventional superconductors at cryogenic temperatures, using polarization-dependent transmission measurements in a specialized cavity system.

Contribution

It presents a novel microwave-based technique employing a TE111 cavity resonator with circular polarization to measure TRSB, differing from traditional optical methods.

Findings

Demonstrated the resonator's ability to detect TRSB signals.

Validated the system with YIG ferrite and CrGeTe3 samples.

Achieved operation at 20 mK in a dilution refrigerator.

Abstract

We present a microwave-frequency method for measuring polar Kerr effect and spontaneous time-reversal symmetry breaking (TRSB) in unconventional superconductors. While this experiment is motivated by work performed in the near infrared using zero-loop-area Sagnac interferometers, the microwave implementation is quite different, and is based on the doubly degenerate modes of a TE$_{111}$ cavity resonator, which act as polarization states analogous to those of light. The resonator system has $in$-$situ$ actuators that allow quadrupolar distortions of the resonator shape to be controllably tuned, as these compete with the much smaller perturbations that arise from TRSB. The most reliable way to the detect the TRSB signal is by interrogating the two-mode resonator system with circularly polarized microwaves, in which case the presence of TRSB shows up unambiguously as a difference between the forward and reverse transmission response of the resonator - i.e., as a breaking of reciprocity. We illustrate and characterize a coupler system that generates and detects circularly polarized microwaves, and then show how these are integrated with the TE$_{111}$ resonator, resulting in a dilution refrigerator implementation with a base temperature of 20 mK. We show test data on yttrium-iron-garnet (YIG) ferrite and the van der Waals ferromagnet CrGeTe$_3$ as an illustration of how the system operates, then present data showing system performance under realistic conditions at millikelvin temperatures.