A method for manufacturing a superconductor is described. A metal assembly precursor can be formed within a hollow copper support element. Forming the metal assembly precursor within a hollow copper support element by positioning a plurality of conductor elements about a core including Sn to provide a first plurality of inner interstitial spaces between the plurality of conductor elements between the core and conductor elements and a second plurality of outer interstitial spaces between the hollow copper support element and the core, the plurality of conductor elements including unreacted Nb. The metal assembly precursor can be reduced via cold drawing to produce a reduced metal assembly. The reduced metal assembly can be reaction heat treated so that the unreacted Nb undergoes a phase transformation to a reacted superconductor.

A method for manufacturing a superconductor is described. A metal assembly precursor can be formed within a hollow copper support element. Forming the metal assembly precursor within a hollow copper support element by positioning a plurality of conductor elements about a core including Sn to provide a first plurality of inner interstitial spaces between the plurality of conductor elements between the core and conductor elements and a second plurality of outer interstitial spaces between the hollow copper support element and the core, the plurality of conductor elements including unreacted Nb. The metal assembly precursor can be reduced via cold drawing to produce a reduced metal assembly. The reduced metal assembly can be reaction heat treated so that the unreacted Nb undergoes a phase transformation to a reacted superconductor.

In various embodiments, superconducting wires incorporate diffusion barriers composed of Ta alloys that resist internal diffusion and provide superior mechanical strength to the wires.

In various embodiments, superconducting wires incorporate diffusion barriers composed of Ta alloys that resist internal diffusion and provide superior mechanical strength to the wires.

Magnets and magnet systems include stacked magnet baseplates. Each of the plates includes grooves that contain windings of a conductor (e.g. a high temperature superconductor) that generates a magnetic field when current is passed through. This field generates Lorentz forces in the stack that press the conductors in different directions and with different magnitudes. Thus, the plates are oppositely oriented (mirrored) so that these forces always press the conductors into the grooves, rather than pulling them out of the grooves. The conductors may be further reinforced in their grooves with solder or epoxy potting. Some stacks may have more plates in one orientation than in the mirrored orientation, because the Lorentz forces need not be symmetrical with respect to a midpoint of the stack, e.g. when the system experiences externally-applied magnetic fields. Additional, mirrored side plates may be added in some configurations.

Magnets and magnet systems include stacked magnet baseplates. Each of the plates includes grooves that contain windings of a conductor (e.g. a high temperature superconductor) that generates a magnetic field when current is passed through. This field generates Lorentz forces in the stack that press the conductors in different directions and with different magnitudes. Thus, the plates are oppositely oriented (mirrored) so that these forces always press the conductors into the grooves, rather than pulling them out of the grooves. The conductors may be further reinforced in their grooves with solder or epoxy potting. Some stacks may have more plates in one orientation than in the mirrored orientation, because the Lorentz forces need not be symmetrical with respect to a midpoint of the stack, e.g. when the system experiences externally-applied magnetic fields. Additional, mirrored side plates may be added in some configurations.

In various embodiments, superconducting wires feature assemblies of clad composite filaments and/or stabilized composite filaments embedded within a wire matrix. The wires may include one or more stabilizing elements for improved mechanical properties.

In various embodiments, superconducting wires feature assemblies of clad composite filaments and/or stabilized composite filaments embedded within a wire matrix. The wires may include one or more stabilizing elements for improved mechanical properties.

Methods and devices for producing reinforced 2212 multifilament superconducting wire with low aspect shape. More specifically, methods and devices for producing reinforced round or rectangular wire with reinforcement strips. Methods and devices for producing cable using the reinforced 2212 multifilament superconducting wire as well as for producing reinforced 2223 Silver tape-based cable.

Methods and devices for producing reinforced 2212 multifilament superconducting wire with low aspect shape. More specifically, methods and devices for producing reinforced round or rectangular wire with reinforcement strips. Methods and devices for producing cable using the reinforced 2212 multifilament superconducting wire as well as for producing reinforced 2223 Silver tape-based cable.