Vanadium–gallium

Vanadium–gallium (V₃Ga) is a superconducting alloy of vanadium and gallium. It is often used for the high field insert coils of superconducting electromagnets.

Vanadium–gallium tape is used in the highest field magnets (magnetic fields of 17.5 T). The structure of the superconducting A15 phase of V₃Ga is similar to that of the more common Nb₃Sn.[1]

In conditions where the magnetic field is higher than 8 T and the temperature is higher than 4.2 K, Nb₃Sn and V₃Ga see use.

The main property of V₃Ga that makes it so useful is that it can be used in magnetic fields up to about 18 T, while Nb₃Sn can only be used in fields up to about 15 T.[2]

The high field characteristics can be improved by doping with high-Z elements such as Nb, Ta, Sn, Pt and Pb.[3]

Physical Properties

Molecular Weight	222.55 g/mol
Melting Point	1720 °C
Highest magnetic field	18 T

[4]

V₃Ga has an A15 phase, which makes it extremely brittle. One must be extremely cautious not to over-bend the wire when handling it. [2]

Superconducting properties

Critical temperature (T_c): ~14.2 K[5]
Upper critical field (H_c2): over 19 T.

Fabrication of superconductive wires or tapes

V₃Ga wires can be formed using solid-state precipitation.[6]

V₃Ga superconducting tape (10 mm × 0.14 mm cross section). A vanadium core is covered with 15 μm V₃Ga layer, then 20 μm bronze (stabilizing layer) and 15 μm insulating layer. Critical current 180 A (19.2 T, 4.2 K), critical current density 20 kA/cm².
An example of a wire (V₃Ga alloy) used in a superconducting magnet.

History

References

Markiewicz, W.; Mains, E.; Vankeuren, R.; Wilcox, R.; Rosner, C.; Inoue, H.; Hayashi, C.; Tachikawa, K. (1977). "A 17.5 Tesla superconducting concentric Nb₃Sn and V₃Ga magnet system". IEEE Transactions on Magnetics. 13 (1): 35–37. Bibcode:1977ITM....13...35M. doi:10.1109/TMAG.1977.1059431.
Ekin, Jack W. (1983). "Superconductors". In Reed, Richard P.; Clark, Alan F. (eds.). Materials at Low Temperatures. Russell, OH: American Society for Metals. pp. 465–513. ISBN 978-1-62708-348-5.
Tedrow, P. M.; Meservy, R. (1984), "Improvement in magnetic field properties of vanadium–gallium superconductors by enhancement of spin-orbit scattering", MIT Report, Bibcode:1984mit..reptR....T
"Vanadium Gallide". American Elements.
Decker, D. L. Laquer, H. L. (1969), "Magnetization Studies on Superconducting Vanadium‐Gallium", Journal of Applied Physics, 40 (7): 2817–2822, Bibcode:1969JAP....40.2817D, doi:10.1063/1.1658081{{citation}}: CS1 maint: multiple names: authors list (link)
Hong, Minghwei (1980), A15 superconductors through direct "solid-state" precipitation: V₃Ga AND Nb₃Al

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[1] Markiewicz, W.; Mains, E.; Vankeuren, R.; Wilcox, R.; Rosner, C.; Inoue, H.; Hayashi, C.; Tachikawa, K. (1977). "A 17.5 Tesla superconducting concentric Nb₃Sn and V₃Ga magnet system". IEEE Transactions on Magnetics. 13 (1): 35–37. Bibcode:1977ITM....13...35M. doi:10.1109/TMAG.1977.1059431.

[Ref1-2] Ekin, Jack W. (1983). "Superconductors". In Reed, Richard P.; Clark, Alan F. (eds.). Materials at Low Temperatures. Russell, OH: American Society for Metals. pp. 465–513. ISBN 978-1-62708-348-5.

[3] Tedrow, P. M.; Meservy, R. (1984), "Improvement in magnetic field properties of vanadium–gallium superconductors by enhancement of spin-orbit scattering", MIT Report, Bibcode:1984mit..reptR....T

[4] "Vanadium Gallide". American Elements.

[5] Decker, D. L. Laquer, H. L. (1969), "Magnetization Studies on Superconducting Vanadium‐Gallium", Journal of Applied Physics, 40 (7): 2817–2822, Bibcode:1969JAP....40.2817D, doi:10.1063/1.1658081{{citation}}: CS1 maint: multiple names: authors list (link)

[6] Hong, Minghwei (1980), A15 superconductors through direct "solid-state" precipitation: V₃Ga AND Nb₃Al