Title :
Nb3Sn coating of high purity Nb cavities
Author :
Dasbach, D. ; Muller, G. ; Peiniger, M. ; Piel, H. ; Roth, R.W.
Author_Institution :
Fachbereich Phys., Bergische Univ., Wuppertal, West Germany
fDate :
3/1/1989 12:00:00 AM
Abstract :
The authors have developed a modified vapor diffusion technique using specially constructed UHV furnaces to produce uniform Nb3 Sn layers on 1- and 3-GHz accelerator cavities without losing the high thermal conductivity of the Nb wall. In a first experiment with a single-cell 3-GHz cavity of medium Nb purity (residual resistivity ratio, RRR=156) they have achieved Eacc=10 MV/m with an 0.6-μm-thick Nb3Sn layer. This is so far the highest accelerating field for their Nb3Sn cavities, but it is low compared to the 25 MV/m achieved in the same cavity before coating. Possible reasons for the reduced breakdown field for Nb3Sn are discussed on the basis of the local thermal breakdown model
Keywords :
cavity resonators; niobium; niobium alloys; particle accelerator accessories; superconducting thin films; tin alloys; type II superconductors; vapour deposition; 1 GHz; 3 GHz; Nb3Sn layers; UHV furnaces; accelerating field; accelerator cavities; breakdown field; high purity Nb cavities; high thermal conductivity; local thermal breakdown model; residual resistivity ratio; vapor diffusion technique; Acceleration; Coatings; Diffusion processes; Furnaces; Heating; Niobium; Niobium-tin; Temperature; Thermal conductivity; Tin;
Journal_Title :
Magnetics, IEEE Transactions on
