This compound superconducting precursor wire includes: a compound superconducting precursor portion including a plurality of compound superconducting precursor filaments, and a first matrix precursor having the plurality of compound superconducting precursor filaments embedded therein and including a first stabilizing material; a reinforcing material portion disposed on an outer peripheral side of the compound superconducting precursor portion; and a stabilizing material portion which is disposed on at least one of an inner peripheral side and an outer peripheral side of the reinforcing material portion, and consisting of a second stabilizing material, in which a Vickers hardness (HV) of the stabilizing material portion is 90 or less, and a 0.2% tensile strength of the compound superconducting precursor wire is 200 MPa or more.

A system comprises a placer, a filler, a heater, and a cooler. The placer places a reinforcement structure within a production casing, wherein the reinforcement structure includes one or more fibers. The filler fills the production casing with high temperature superconducting (HTS) component powder. The heater heats the production casing with the reinforcement structure and the HTS component powder to generate liquefied HTS material from the HTS component powder. The cooler cools the liquefied HTS material to generate a solid HTS crystal.

A system comprises a placer, a filler, a heater, and a cooler. The placer places a reinforcement structure within a production casing, wherein the reinforcement structure includes one or more fibers. The filler fills the production casing with high temperature superconducting (HTS) component powder. The heater heats the production casing with the reinforcement structure and the HTS component powder to generate liquefied HTS material from the HTS component powder. The cooler cools the liquefied HTS material to generate a solid HTS crystal.

A superconducting wire comprises a MgB.sub.2 filament, a base material, a high-thermal expansion metal, and a stabilizing material. The high-thermal expansion metal is a metal (for example, stainless steel) having a higher thermal expansion coefficient at room temperature than the MgB.sub.2 and the base material (for example, iron or niobium). The manufacturing method includes a step of packing a mixed powder in a first metal pipe, a step of performing wire-drawing on the first metal pipe formed of the metal to be the base material, a step of producing a composite wire by accommodating the first metal pipe in a second metal pipe formed of the high-thermal expansion metal and the stabilizing material, a step of performing wire-drawing on the composite wire, and a step of performing heat treatment.

A superconducting wire comprises a MgB.sub.2 filament, a base material, a high-thermal expansion metal, and a stabilizing material. The high-thermal expansion metal is a metal (for example, stainless steel) having a higher thermal expansion coefficient at room temperature than the MgB.sub.2 and the base material (for example, iron or niobium). The manufacturing method includes a step of packing a mixed powder in a first metal pipe, a step of performing wire-drawing on the first metal pipe formed of the metal to be the base material, a step of producing a composite wire by accommodating the first metal pipe in a second metal pipe formed of the high-thermal expansion metal and the stabilizing material, a step of performing wire-drawing on the composite wire, and a step of performing heat treatment.

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

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

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

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