A potentially cost-saving and performance-enhancing new approach to fabricating superconducting radiofrequency (SRF) accelerating cavities has been demonstrated by the Institute for Superconducting Radiofrequency Science & Technology (ISRFST) at Jefferson Lab in Newport News, Virginia.
Several single-cell niobium cavities were made from material sliced from large-grain niobium ingots – rather than fine-grain material melted from ingots and formed into sheets by the traditional process of forging, annealing, rolling and chemical etching.
In tests carried out by ISRFST, these cavities performed extremely well. If multi-cell cavities are also successful, the method could have a substantial impact on the economics of high-performance RF superconductivity.
The work aimed to provide a deeper understanding of the influence of grain boundaries on the often-observed drop in Q (the cavity-performance quality factor) at accelerating gradients above 20 MV/m.
“Q-drop” is not well understood, but it may be linked to contaminants and grain boundaries in the niobium.
The researchers used single-crystal niobium sheets for forming into half-cells, omitting expensive processing steps and producing cavities with few or no grain boundaries. Reference Metals Company Inc of Bridgeville, Pennsylvania, provided the niobium in a research collaboration with JLab.
This proof-of-principle work could have wide repercussions. Most notably, it could lead to more reliable production and reduced costs.
The research also has important implications for the forthcoming International Linear Collider (ILC), a 500 GeV machine that will need some 17,000 SRF cavities performing above 28 MV/m. Using a scaled version of a low-loss design proposed for the ILC, a test cavity supported an accelerating gradient of 45 MV/m. This figure is very close to both Cornell’s current world record and the theoretical limit.
