📝 SummarXiv

Abstract

Superconducting radio-frequency (SRF) cavities are the leading technology for highly efficient particle acceleration, and their performance can be significantly enhanced through the controlled introduction of interstitial impurities into bulk niobium. Nitrogen doping has demonstrated a substantial reduction in surface resistance losses, which improves the quality factor of the cavities. More recently, oxygen doping has emerged as a promising alternative, demonstrating comparable reductions in surface resistance. In this study, we combine cavity measurements on \SI{1.3}{GHz} niobium SRF cavities subjected to a range of nitrogen- and oxygen-based treatments with material characterizations performed on cavity cutouts processed under identical conditions. This approach allows us to quantitatively assess the contribution of each impurity to the reduction of surface resistance. We find that nitrogen is ten times more effective than oxygen in reducing surface resistance at \SI{16}{MV/m}. We propose a model to explain this variation, suggesting that nitrogen more effectively traps hydrogen, thus suppressing the formation of niobium hydrides within the RF penetration layer and enabling an improved superconducting gap.