Methods and structures corresponding to superconducting apparatus including superconducting layers and traces are provided. A method for forming a superconducting apparatus includes forming a first dielectric layer on a substrate by depositing a first dielectric material on the substrate and curing the first dielectric material at a first temperature. The method further includes forming a first superconducting layer comprising a first set of patterned superconducting traces on the first dielectric layer. The method further includes forming a second dielectric layer on the first superconducting layer by depositing a second dielectric material on the first superconducting layer and curing the second dielectric material at a second temperature, where the second temperature is lower than the first temperature. The method further includes forming a second superconducting layer comprising a second set of patterned superconducting traces on the second dielectric layer.

A superconductor device includes a high superconductivity transition temperature enhanced from the raw material transition temperature. The superconductor device includes a matrix material and a core material. The enhancing matrix material and the core material together create a system of strongly coupled carriers. A plurality of low-dimensional conductive features can be embedded in the matrix. The low-dimensional conductive features (e.g., nanowires or nanoparticles) can be conductors or superconductors. An interaction between electrons of the low-dimensional conductive features and the enhancing matrix material can promote excitations that increase a superconductivity transition temperature of the superconductor device.

A superconducting layer joint structure of embodiments includes: a first superconducting layer; a second superconducting layer; and a joint layer provided between the first superconducting layer and the second superconducting layer and containing a plurality of crystal particles containing a rare earth element (RE), barium (Ba), copper (Cu), and oxygen (O). The plurality of crystal particles includes at least one first particle. The at least one first particle has a first inner region and a first outer region. The first inner region is disposed inside the first superconducting layer. The first outer region is disposed outside the first superconducting layer.

Operational characteristics of an high temperature superconducting (HTS) film comprised of an HTS material may be improved by depositing a modifying material onto appropriate surfaces of the HTS film to create a modified HTS film. In some implementations of the invention, the HTS film may be in the form of a c-film. In some implementations of the invention, the HTS film may be in the form of an a-b film, an a-film or a b-film. The modified HTS film has improved operational characteristics over the HTS film alone or without the modifying material. Such operational characteristics may include operating in a superconducting state at increased temperatures, carrying additional electrical charge, operating with improved magnetic properties, operating with improved mechanic properties or other improved operational characteristics. In some implementations of the invention, the HTS material is a mixed-valence copper-oxide perovskite, such as, but not limited to YBCO. In some implementations of the invention, the modifying material is a conductive material that bonds easily to oxygen, such as, but not limited to, chromium.

A superconductor device includes a high superconductivity transition temperature enhanced from the raw material transition temperature. The superconductor device includes a matrix material and a core material. The enhancing matrix material and the core material together create a system of strongly coupled carriers. A plurality of low-dimensional conductive features can be embedded in the matrix. The low-dimensional conductive features (e.g., nanowires or nanoparticles) can be conductors or superconductors. An interaction between electrons of the low-dimensional conductive features and the enhancing matrix material can promote excitations that increase a superconductivity transition temperature of the superconductor device.

Electrical, mechanical, computing, and/or other devices that include components formed of extremely low resistance (ELR) materials, including, but not limited to, modified ELR materials, layered ELR materials, and new ELR materials, are described.

An oxide superconducting wire includes a superconducting layer formed disposed on a substrate. The superconducting layer includes a structure in which artificial pin rods having different lengths dispersed on a plane parallel to a substrate surface of the substrate. A degree of dispersion in length of the artificial pin rods in the plane parallel to the substrate surface is greater than or equal to 5 mm.

There is provided methods of manufacturing a superconductor element and a method of manufacturing a phononic element. The method of manufacturing a superconductor element comprises the step of forming a periodic patterned structure in a material to alter an electronic structure in a primary layer (M) of the material to couple with the or each phonon of the primary layer (M) so as to induce superconductivity in the primary layer (M) or modify the superconductivity of the primary layer, and/or create or alter one or more phonons in a primary layer (M) of the material to couple with the electrons of the primary layer (M) so as to induce superconductivity in the primary layer (M) or modify the superconductivity of the primary layer. The method of manufacturing a phononic element comprises the steps of: providing one of a primary layer (M) and a secondary layer (M2) of a material on the other of the primary layer (M) and secondary layer (M2) of the material; and forming a periodic patterned structure in the secondary layer (M2) to create or alter one or more phonons in the primary layer (M).

The invention relates to a method for producing a composite comprising a high-temperature superconductor (HTS) layer based on rare earth metal-barium-copper oxide on a substrate with defined biaxial texture, having the following steps: applying a first HTS coating solution to the substrate, drying the first HTS coating solution to produce a first film, pyrolyzing the first film to produce a first pyrolyzed sublayer, removing an interfacial layer on the upper side of the first pyrolyzed sublayer to produce a first pyrolyzed sublayer with reduced layer thickness, applying a second HTS coating solution to the first pyrolyzed sublayer with reduced layer thickness, drying the second HTS coating solution to produce a second film, pyrolyzing the second film to produce a second pyrolyzed sublayer, optionally forming one or more further pyrolyzed sublayers on the second pyrolyzed sublayer, and crystallizing the overall layer formed from the pyrolyzed sublayers to complete the HTS layer, wherein the removal of the interfacial layer in step D) is effected in such a way that a texture determined by the defined biaxial texture of the substrate is transferred to the first and also to the second pyrolyzed sublayer, and also to a product producible by such a method.

Electrical, mechanical, computing, and/or other devices that include components formed of extremely low resistance (ELR) materials, including, but not limited to, modified ELR materials, layered ELR materials, and new ELR materials, are described.