The subject matter of the present disclosure may be embodied in devices, such as flexible wiring, that include: an elongated flexible substrate; multiple electrically conductive traces arranged in an array on a first side of the elongated flexible substrate; and an electromagnetic shielding layer on a second side of the elongated flexible substrate, the second side being opposite the first side, in which the elongated flexible substrate includes a fold region between a first electronically conductive trace and a second electrically conductive trace such that the electromagnetic shielding layer provides electromagnetic shielding between the first electronically conductive trace and the second electrically conductive trace.

An ultra-thin film superconducting tape and method for fabricating same is disclosed. Embodiments are directed to a superconducting tape being fabricated by processes which include removing a portion of the superconducting tape's substrate subsequent the substrate's initial formation, whereby a thickness of the superconducting tape is reduced to 15-80 m.

The present disclosure relates to a method for coating a surface (110B) of a structure (110), the method comprising steps of: placing a structure (110) inside a chamber, at least one ejector (104) being located inside the chamber and oriented towards a surface (110B) to be coated of the structure; enclosing the chamber; forming a vacuum in the chamber; and then injecting vapor through the at least one ejector (104) towards the surface, while causing a relative motion, for example rotation. between the structure and the at least one ejector.

Provided is a superconducting wire. The superconducting wire comprises a substrate, a superconducting film on the substrate and a pinning center in the superconducting film. The superconducting film includes Y.sub.1-xRE.sub.xBCO and the pinning center has an additive of Ba.sub.2YNbO.sub.6.

A terminal for a superconducting wire, a superconducting rotary machine having the same, and a method for manufacturing the terminal may improve the cooling efficiency and reduce the weight of a superconducting rotary machine. The terminal may include a frame having a hollow portion and having an open surface formed on at least one side thereof and may include a superconductor filled in the hollow portion. An end of a superconducting wire may be coupled to at least the superconductor.

A device comprises a solenoid of reinforced HTS material, wherein the solenoid of reinforced HTS material comprises a plurality continuous ordered fibers embedded in a high temperature superconducting material. A device comprises one or more coils, wherein the one or more coils comprise HTS solenoids; an armature coupled to a stem in a control valve, wherein the armature comprises a HTS solenoid; and coolant access paths, wherein the coolant access paths enable cooling the one or more coils and the armature. A device comprises a photovoltaic cell; and a parallel array of HTS solenoids, wherein the parallel array of HTS solenoids is coupled to the photovoltaic cell.

A purpose of the present invention is to provide a coated conductor having a high critical current and low AC loss. The high-temperature superconducting coated conductor that achieves this purpose has an elongated first metal substrate, and multiple filaments arranged on the first metal substrate so as to extend in a longitudinal direction of the first metal substrate. The multiple filaments are arranged approximately in parallel with gaps therebetween, and each filament includes, in order from the first metal substrate side, a first superconducting layer containing a rare earth element, first stabilizing layers, second stabilizing layers, and a second superconducting layer containing a rare earth element.

A device comprises a tube with a tube HTS solenoid, wherein a projectile in a sabot comprising a sabot HTS solenoid. A method comprises disposing a seed HTS crystal on a growing crystal in contact with an a-b plane of the seed HTS crystal to grow the growing crystal, wherein the a-b plane is perpendicular to a c-axis. A method comprises disposing a seed HTS crystal on a growing crystal in contact with a b-c plane of the seed HTS crystal to grow the growing crystal, wherein the b-c plane is perpendicular to an a-axis. A device comprises a reinforced HTS material in a graphene casing, wherein the HTS in the graphene casing includes a cooling channel and a return channel.

A method for forming a plurality of filaments, such that each filament is superconducting. The method includes providing a substrate having first and second sides. The substrate has a plurality of grooves in the first side of the substrate having a coating of a superconducting material so that for each groove within the plurality of grooves. A first part of the coating on a first side of a feature of the groove is separated from a second part of the coating on a second side of the feature of the groove. The second side of the feature of the groove is opposite of the first side of the groove, with removing from the second side of the substrate, at least a part of the substrate, to remove at least a connection from the first part of the coating to the second part of the coating via the substrate.

Provided is a superconducting wire. The superconducting wire comprises a substrate, a superconducting film on the substrate and a pinning center in the superconducting film. The superconducting film includes Y.sub.1-xRE.sub.xBCO and the pinning center has an additive of Ba.sub.2YNbO.sub.6.