Title :
Neutron irradiation effects on A15 multifilamentary wires
Author :
Haindl, S. ; Eisterer, M. ; Müller, R. ; Prokopec, R. ; Weber, H.W. ; Müller, M. ; Kirchmayr, H. ; Takeuchi, T. ; Bargioni, L.
Author_Institution :
Atomic Inst. of the Austrian Univ., Vienna, Austria
fDate :
6/1/2005 12:00:00 AM
Abstract :
Whereas Nb3Sn wires are commercially available and produced in long lengths for the fabrication of large high field magnets, Nb3Al is emerging as a candidate material for even higher fields, particularly for nuclear fusion devices. We are therefore investigating the basic superconducting parameters of both materials, such as the transition temperature, the critical current densities and the upper critical fields, as a function of gamma dose and fast neutron fluence. Whereas the transition temperature of these multifilamentary wires is found to decrease slightly, both JC and the upper critical fields (as determined from Kramer plots) increase with neutron fluence, in agreement with previous work on A15 systems. The enhancement of the critical currents amounts to approximately 15%. Further irradiation work to higher fluences is under way, in order to investigate the limits of these materials for applications in a radiation environment.
Keywords :
aluminium alloys; critical current density (superconductivity); multifilamentary superconductors; niobium alloys; superconducting magnets; superconducting tapes; superconducting transition temperature; tin alloys; type II superconductors; A15 multifilamentary wires; Nb3Al; Nb3Sn; critical current density; fast neutron fluence; high field magnets; neutron irradiation effects; nuclear fusion devices; superconducting parameters; transition temperature; Fabrication; Fusion reactors; Magnetic materials; Magnets; Neutrons; Niobium; Superconducting materials; Superconducting transition temperature; Tin; Wires; A15; multifilamentary wires; neutron irradiation;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.848950
