Grain-boundary structure and segregation in Nb3Sn coatings on Nb for high-performance superconducting radiofrequency cavity applications
Jaeyel Lee, Zugang Mao, Kai He, Zu Hawn Sung, Tiziana Spina, Sung-Il, Baik, Daniel L Hall, Matthias Liepe, David N Seidman, Sam Posen

TL;DR
This study investigates the atomic-scale structure and composition of grain boundaries in Nb3Sn coatings on Nb, revealing how processing conditions influence segregation and how this impacts superconducting cavity performance.
Contribution
It provides new insights into controlling grain boundary chemistry in Nb3Sn coatings to optimize superconducting radiofrequency cavity performance.
Findings
Sn segregation at grain boundaries can be controlled by process parameters.
Best cavity performance correlates with minimal Sn segregation at grain boundaries.
Post-annealing alters the segregation profile, affecting superconducting properties.
Abstract
We report on atomic-scale analyses of grain boundary (GB) structures and segregation in Nb3Sn coatings on Nb, prepared by the vapor-diffusion process, for superconducting radiofrequency (SRF) cavity applications, utilizing atom-probe tomography, high-resolution scanning transmission electron-microscopy and first-principles calculations. We demonstrate that the chemical composition of Nb3Sn GBs is correlated strongly with the diffusion of Sn and Nb at GBs during the coating process. In a sample coated with a relatively large Sn flux, we observe an interfacial width of Sn segregation at a GB of ~3 nm, with a maximum concentration of ~35 at.%. After post-annealing at 1100 oC for 3 h, the Sn segregated at GBs disappears and Nb segregation is observed subsequently at GBs, indicating that Nb diffused into the Nb3Sn GBs from the Nb substrate. It is also demonstrated that the amount of Sn…
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