Microwave loss characterization using multi-mode superconducting resonators

TL;DR

This paper introduces a novel single-resonator method for measuring microwave losses in materials and interfaces, enabling detailed analysis of loss mechanisms in superconducting quantum circuits.

Contribution

It presents a formalism and design strategies for multi-mode superconducting resonators to characterize material losses with a single device, improving upon previous methods.

Findings

Chemical etching and diamond turning reduce surface dielectric and conductor losses.

Surface coatings significantly decrease all measured losses.

Chemical etching creates a thinner oxide layer, improving dielectric loss.

Abstract

Measuring the losses arising from different materials and interfaces is crucial to improving the coherence of superconducting quantum circuits. Although this has been of interest for a long time, current studies can either only provide bounds to those losses, or require several devices for a complete characterization. In this work, we introduce a method to measure the microwave losses of materials and interfaces with a single multi-mode superconducting resonator. We demonstrate a formalism for analyzing the loss sensitivity of multi-mode systems and discuss the design strategies of multi-mode resonators for material loss studies. We present two types of multi-mode superconducting resonators for the study of bulk superconductors: the forky whispering-gallery-mode resonator (FWGMR) and the ellipsoidal cavity. We use these resonators to measure the surface dielectric, conductor, and seam losses of high-purity (5N5) aluminum and aluminum alloy (6061), as well as how they are affected by chemical etching, diamond turning, and thin-film coating. We find that chemical etching and diamond turning reduce both the surface dielectric and conductive losses of high-purity aluminum, but provide no appreciable improvement to the seam. Coating the surfaces of diamond-turned aluminum alloys with e-beam evaporated or sputtered aluminum thin-films significantly reduces all three losses under study. In addition, we study the effect of chemical etching on the surface of high-purity aluminum using transmission electron microscopy (TEM) and find that the chemical etching process creates a thinner and more uniform oxide layer, consistent with the observed improvement in the surface dielectric loss.