Flux expulsion in niobium superconducting radio-frequency cavities of different purity and essential contributions to the flux sensitivity
Pashupati Dhakal, Gianluigi Ciovati, Alex Gurevich

TL;DR
This study investigates how the purity and surface treatments of niobium cavities affect flux trapping sensitivity, revealing that lower purity increases trapped flux and surface treatments significantly influence flux sensitivity, with implications for optimizing superconducting RF cavity performance.
Contribution
It provides experimental data on flux trapping sensitivity in niobium cavities of varying purity and surface treatments, and offers a theoretical analysis of pinning mechanisms affecting flux sensitivity.
Findings
Lower purity niobium results in higher trapped flux.
Surface treatments significantly alter flux sensitivity parameter $S$.
Pinning mechanisms involve weak surface pinning regions affecting vortex oscillations.
Abstract
Magnetic flux trapped during the cooldown of superconducting radio-frequency cavities through the transition temperature due to incomplete Meissner state is known to be a significant source of radio-frequency losses. The sensitivity of flux trapping depends on the distribution and the type of defects and impurities which pin vortices, as well as the cooldown dynamics when the cavity transitions from a normal to superconducting state. Here we present the results of measurements of the flux trapping sensitivity on 1.3 GHz elliptical cavities made from large-grain niobium with different purity for different cooldown dynamics and surface treatments. The results show that lower purity material results in a higher fraction of trapped flux and that the trapped flux sensitivity parameter is significantly affected by surface treatments but without much change in the mean free path . We…
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