Microscopic Investigation of rf Vortex Nucleation in Nb3Sn Films Using a Near-Field Magnetic Microwave Microscope

TL;DR

This study employs a near-field magnetic microwave microscope to analyze rf vortex nucleation in Nb3Sn films, revealing how fabrication methods influence vortex behavior and demonstrating a sensitive local defect detection technique.

Contribution

It introduces a novel application of third-harmonic response measurement to distinguish vortex nucleation characteristics in differently fabricated Nb3Sn films.

Findings

Electrochemically plated Nb3Sn shows additional vortex-related features at higher temperatures.

Both films exhibit signatures of vortex nucleation below 7 K.

Fabrication method affects vortex penetration and defect-related responses.

Abstract

We use a near-field magnetic microwave microscope to investigate and compare rf vortex nucleation in two superconducting radio-frequency (SRF)-quality Nb3Sn films fabricated by different methods: a conventional vapor-diffused film and an electrochemically plated film followed by thermal annealing, both of which are deposited on Nb substrates. The microscope applies a localized rf magnetic field to the sample surface and measures the resulting third-harmonic response P3f, which is particularly sensitive to rf vortex nucleation triggered by surface defects. Both Nb3Sn films exhibit nontrivial P3f(T) structures below 7 K that display the key signatures associated with rf vortex nucleation at local defects. The electrochemical film additionally shows multiple P3f(T) structures between 14 K and 16 K that are absent in the vapor-diffused sample. Our results highlight the influence of fabrication method on rf vortex penetration properties and demonstrate the utility of third-harmonic response as a local diagnostic tool for surface defects in Nb3Sn films.