Abstract
| The inhibition of Nb$_3$Sn grain growth in the presence of ZrO$_2$ nanoparticles appears to be one of
the most promising method for pushing the critical current densities of Nb$_3$Sn superconducting
wires to levels that meet the requirements set for the Future Circular Collider. We have investigated
the effect of ZrO$_2$ nanoparticles formed by the internal oxidation of Zr on the superconducting
properties and microstructure of Nb3Sn formed from Nb-1 wt%Zr, Nb-7.5 wt%Ta,
Nb-7.5 wt%Ta-1 wt%Zr and Nb-7.5 wt%Ta-2 wt%Zr alloys. A monofilamentary wire
configuration was used, with a 0.22 mm outer diameter Nb-alloy tube containing a core of
powdered metal oxide (SnO$_2$, CuO or MoO$_3$) as oxygen source and successive deposits of Cu, Sn
and Cu on the outer surface. As determined from inductive measurements, the layer critical current
densities of the samples based on Nb alloys with internally oxidized Zr were superior to those based
on Nb-7.5 wt%Ta. The samples based on Nb-7.5 wt%Ta-1 wt%Zr and Nb-7.5 wt%Ta-2 wt%Zr
showed higher critical current densities at high magnetic fields (above 10–15 T), and upper critical
fields exceeding 28.5 T at 4.2 K (99% normal state resistivity criterion). A record value of 29.2 T of
the upper critical field at 4.2 K was obtained on samples based on Nb-7.5 wt%Ta-2 wt%Zr.
Hypotheses are proposed and discussed for explaining this unexpected increase of the upper
critical field, by considering the possible effects of non-oxidized Zr on the superconducting
properties of Nb3Sn and of the oxidized Zr on the formation and microchemistry of Nb$_3$Sn.
Regardless of sample type the Nb3Sn grains observed in our samples have an aspect ratio of 1.5–1.7.
When compared in the short axis direction, the mean distance between grain boundary intercepts
(lineal intercept method) is ∼40% smaller in the samples with internally oxidized Zr than in the
reference samples based on Nb-7.5 wt%Ta. In the long axis direction the reduction is of 20%–30%. |