Effects of neutron irradiation on the critical current densities of (Nb-1 at.% U)3Sn multifilamentary composites

Multifilamentary Nb3Sn composite conductors with 65 880 and 421 160 filaments have been fabricated in long lengths by the internal tin-diffusion method. Filament diameters are in the range from 31.1 nm to 274 nm. Conductors were heat treated for 1 to 53 days at various temperatures from 400°C to 700

The critical current degradation of multifilamentary NbsSn superconducting composites strained mechanically at room temperature has been investigated. The experimental results show that the effects of the Nb$n layer thickness and the speci.men wire structure, such as monolithic and stranded cable on

The upper critical field Hc2(T) of the A15 compound has been measured as a function of temperature T for various compositions and levels of irradiation with fast reactor neutrons. Compositions ranging from 19 to 29 at % Pt and neutron fluences up to 16 • 101Sn/cme (E> 1 Me V) were studied. A sto&hio

Specimens of Nb3Sn have been irradiated by fast neutrons at 70°C to doses in the range 3 x 1021 neutrons m -2 to 9 x 1023 neutrons m -2. Their critical temperatures were depressed linearly with dose, to less than 4.2 K after about 3 x 1023 neutrons m "2. The critical temperature recovered to their i

A.c. losses for a practical bronze-processed Nb3Sn multifilamentary composite were measured over a wide range of amplitudes (0 ~ B m ~< 14 T, 0 ~Bdc <~ 1 0 T) in transverse magnetic field with trapezoidal wave forms. The composite had a Nb or Ta barrier for ptoecting the Cu stabilizer from Sn diffus