FR3142596A1 - Superconducting wire composed of base metals and a non-metal such as for example Dysprosium, Neodymium, Tin, Selenium, and possible additive compounds, used at room temperature and at room pressure, and its manufacturing process . - Google Patents

Abstract

The subject of the present invention is a superconducting wire composed of base metals and a non-metal such as for example Dysprosium, Neodymium, Tin, Selenium, and possible additive compounds, used at ambient temperature and pressure. ambient, and its manufacturing process.

Description

Superconducting wire composed of base metals and a non-metal used at high critical temperatures and its manufacturing process.

The subject of the invention is a superconducting wire composed of base metals and a non-metal such as for example Dysprosium, Neodymium, Tin, Selenium, and possible additive compounds, used at room temperature and at pressure ambient, and its manufacturing process. More precisely, it concerns the production of superconducting elements of elongated shape, such as wires, ribbons and cables which are capable of conducting a high intensity electric current in the direction of the length of the wire. Superconducting wires can be used in several applications such as electronics, aeronautics, energy, transport, medicine.

State of the art :

Superconducting materials such as mixed copper oxides of the type discovered by Bednorz and Müller in 1986 can operate at temperatures higher than those of liquid helium, particularly above the temperature of liquid nitrogen, because their critical temperature Tc is much higher. For the TlBaCaCuO type family, Tc is between 80 and 125K. Which is very advantageous due to the cost of liquid nitrogen. However, the production of superconducting elements such as filaments, ribbons, strips, or cables from these ceramic-type superconducting materials poses certain problems in obtaining high critical currents or producing a reasonably flexible conductor and ensuring resistance. mechanics and chemistry of superconducting wires.

Indeed, the current conductive elements made from ceramic superconducting materials such as YBaCuO are formed of sintered grains and the transport properties of these conductors are those of the solid sinter. It is therefore difficult to obtain flexible wires from these ceramic materials because after sintering the ceramic obtained is fragile. It should also be noted that increasing the critical current requires eliminating impurities at the grain boundary. Furthermore, one of the factors responsible for the lowering of the critical density lies in the anisotropy of the material with respect to the base plane and in the base plane. This is the case in YbaCuO with randomly oriented grains. The CuO₂ planes of high conductivity are misaligned and part of the current must pass along the axis of low electrical conductivity to pass from one crystal to another.

Patent EP3951806 discloses a superconducting wire essentially based on oxide and a laminated longitudinal profile to constitute the superconducting wire which is therefore in this state up to a temperature close to liquid nitrogen.

Patent EP2728592 discloses a superconducting wire which has the same laminated long profile as patent EP3951806 and based on oxide, which is therefore in this state up to a temperature close to liquid nitrogen.

Patent WO202105409 discloses an oxide-based current switch, of the YBACuO type, which is therefore in this state up to a temperature close to liquid nitrogen.

Patent US2019379145 discloses a superconducting wire essentially based on oxide and a laminated longitudinal profile to constitute the superconducting wire which is therefore in this state up to a temperature close to liquid nitrogen.

It is therefore useful to specify that none of the currently known processes makes it possible to obtain superconducting elements of elongated shape, having high critical current densities and good mechanical and chemical properties at ambient pressure and at ambient temperature.

Furthermore, there are numerous works concerning superconductivity and many publications, both theoretical and practical (US, JP, FR, RU, CN). It is possible to cite, for example, the book by Alexander Gabovitch Superconductors – New Developments which presents some articles of general interest.

The phenomenon of superconductivity was discovered in 1911 by the Dutch physicist Heike Kamerlingh Onnes who showed that at very low temperatures, a few Kelvins, certain metals change their physical properties. In particular, the electrical resistance of these materials becomes lower than any measurable value. Thus a direct electric current can circulate without dissipation of energy, therefore almost indefinitely.

There is a transition from the normal conducting state to the superconducting state. This transition occurs at a temperature qualified as a critical temperature. In 1933, W. Meissner and R. Ochsenfeld observed that apart from the exceptional conduction qualities, these metals have the property of excluding any penetration of an external magnetic field thanks to the circulation of super-currents in the superconductor. This effect of non-penetration of the magnetic field is called Meissner effect.

A microscopic theory was put forward in 1957 by John Bardeen, Leon N. Cooper and John Schrieffer (all three Nobel Prize winners in physics in 1972) to explain superconductivity. This theory explains that at very low temperatures, electrons pair (Cooper pair) via lattice phonons.

The theoretical explanation of superconductivity at very low temperatures is based on the fact that Cooper pairs, made up of two electrons, ultimately form bosons which, in turn, can be found in large numbers in the same physical state, occurring in a lower energy state. They do not lose energy through dissipation, and therefore propagate without resistance.

The discovery in 1986 by Johannes Georg Bednorz and Karl Alexander Müller of superconductivity in a synthetic oxide of copper, lanthanum and barium at a critical temperature of 35 K, higher than any known until then, had a considerable impact. This discovery then relaunched research in this area, and allowed the demonstration of this phenomenon up to 164 K, in 1998.

However, to date, there is no complete theory to explain the superconducting phenomenon.

It is customary to qualify the non-dissipative state by three main quantities: the critical temperature, Tc, the critical field Hc and the critical current density. The state of superconductivity characterizes most metals provided that the temperature is very close to 0 K. The temperature below which a material becomes superconductive is then called critical temperature. Superconductivity is obtained at higher temperatures Tc for metals that are poor conductors in the normal state, such as mercury and lead. Temperature has an important influence on other characteristics of a superconducting material such as magnetic field, resistivity or penetration depth. Furthermore, the superconducting state can disappear for an external magnetic field of a certain intensity Hc depending on the temperature.

Superconductors are divided into two categories: type I and type II. Type I superconductors are characterized by the fact that the Meissner effect (the magnetic field lines are expelled from the material except over a very thin thickness) stops abruptly from Hc. For type II superconductors, perfect diamagnetism gradually disappears from a magnetic field value Hc1 and the total disappearance of diamagnetism is produced for a field Hc2.

Type II superconductors are generally made up of alloys (Nb-Zr, Nb-Ti), and transition metals with high resistivity in the normal state. For field values between Hc1 and Hc2, these materials present zones in the normal state, in which the magnetic induction is non-zero. These zones (whose approximate surface area is calculated from the coherence length of the Cooper pairs) are kinds of domains and are surrounded by induced currents, called vortices or vortices separated by superconducting zones in which B = 0 and where close the lines of swirling currents.

The critical current density corresponds to the maximum value beyond which an electric field appears. For type I superconductors, the current distribution is not homogeneous. The transport current flows only at the surface, in the London penetration thickness. For type II superconductors, the critical current density is strongly dependent on induction B and therefore on the presence of vortices in the structure of the material. For transverse induction, in the mixed state, an ideal superconductor has zero current density. The transport current reacts with the vortices and these move when the Lorentz force is greater than the anchoring forces, leading to dissipation in the material. When the current density exceeds a critical value Jc the vortices are torn off.

The present invention is new and inventive.

The present invention relates to a superconducting wire of elongated shape such as a strip, a ribbon or a cable which has improved properties, composed of base metals and a non-metal such as for example Dysprosium, Neodymium, Tin, Selenium, and possible additive compounds, used at room temperature and at room pressure, and its manufacturing process.

The present invention will appear better on reading the figures.

There is a stylized 3D view of the basic crystal structure of the invention.

There is a stylized long view of the basic crystal structure of the invention.

There is a long view of a wire according to one embodiment of the invention.

There is a sectional view of a wire according to one embodiment of the invention.

There is a sectional view of a cable according to one embodiment of the invention.

There is a long view of a cable according to one embodiment of the invention.

There is a stylized view according to another embodiment of the invention.

There is a stylized view according to another embodiment of the invention.

There is a sectional view of a wire according to another embodiment of the invention.

Description of the invention:

The present invention relates to a superconducting wire of elongated shape such as a wire, a strip, a ribbon or a cable which has improved properties, composed of base metals and a non-metal such as for example Dysprosium, Neodymium, Tin, Selenium, and possible additive compounds, used at room temperature and at room pressure, and its manufacturing process.

Below is an argument for the choice of metals and non-metals of the constituents of the superconducting part of the superconducting wire, to avoid using copper Cu and/or oxygen O (the oxides).

The superconducting wire is theoretically represented by a Hamiltonian.

This Hamiltonian can present a kinetic energy term, a free energy term, a periodic potential term, a spin-orbit coupling term, a spin-spin coupling term, a spin-boson coupling term, a term electromagnetic interaction.

Furthermore, in a crystal structure (a sample), for an electron in the conduction band, it has a total angular momentum J equal to 1/2. The dimension along the propagation axis (z) is generally larger than that of the dimensions in the plane (x, y) of the sample considered. It is this axis which is taken into consideration for the angular momentum of the electron. The negatively charged electron can have two possible states; a spin state -1/2 represented by |↓>z or a spin state +1/2 denoted by |↑>z. Similarly, the angular momentum of a hole along the z axis Jz =-3/2 is denoted by its spin state |⇓>z or an angular momentum Jz=+3/2 with a spin state denoted |⇑ >z.

Furthermore, photons are bosonic particles with an integer spin. Photons left circularly polarized |L> or photons right circularly polarized |R> have an angular momentum projection equal to −1 or +1, respectively. Thus, when a circularly polarized photon is absorbed by a transition of the system, the angular momentum must be conserved by the system.

Conservation of angular momentum results in only opposite spin configurations being allowed ( |↑⇓>z or |↓⇑>z ). In the case where the spins of the hole and the electron are in the same direction, the total angular momentum of the two spin states will be equal to ±2. In the electric dipole approximation, light cannot excite these transitions called dark states (|↑⇑>z or |↓⇓>z ). Bright states correspond to antiparallel spin states ( |↑⇓>z or |↓⇑>z ) which interact with circular polarization ( |L>, |R> ).

Additionally, the electromagnetic description in the superconducting part/layer of the superconducting wire can be approximated by a cavity. The cavity is characterized by its electromagnetic field inside it. It is possible to describe this field quantumly by breaking it down into modes. Each mode evolves as a harmonic oscillator of frequency ωmode.

Considering only the fundamental mode of the cavity with frequency ωc, the Hamiltonian of the cavity is written: Ĥcav = ωcâ†â. In which â (respectively â†) is the operator associated with the annihilation (respectively creation) of a photon in the fundamental mode. The ground state of this Hamiltonian, also called empty state |0>, corresponds to an empty cavity without photons. State |1> corresponds to one photon inside the cavity, |2> corresponds to two photons and so on.

Considering the cavity initially in the state |0>, the higher energy state |1> is obtained by applying the creation operator â†. The transformation from state |1> to state |0> is obtained by applying the operator â.

In the case of resonant excitation, the field considered as incident interacts with the fundamental mode of the cavity. The incident electromagnetic field described by the operator ĉin will couple with the fundamental mode of the cavity and this operator is proportional to the electric field operator Êin which is generally normalized so that the quantity <ĉ†in ĉin > is equal to the number of incident photons per unit of time. The field considered to exit after interaction with the cavity is described by the operator ĉout also normalized so that the quantity <ĉ†out ĉout> is equal to the number of photons emitted per unit of time.

Furthermore, according to the Pauli exclusion principle and depending on the conservation of angular momentum, to electromagnetically generate an electron with a state |↓⇑>z it is necessary to create an electron-hole pair of state

|↓⇑>z . For the angular momentum to be conserved, the incident photon must have a polarization state |R> and we therefore deduce that the transition |↑>z to |↑↓⇑>z is only excitable by the circular polarization |R >. It is the same for the transition |↓>z to |↓↑⇓>z which is only excitable by circular polarization

|L>. These selection rules are also valid for a confined hole.

Furthermore, taking into account the distances between each atom of the superconducting part/layer of the superconducting wire, i.e. from a few angstroms to a few nanometers, the tunneling effect is possible between the different metals/or alloys and the coherence length for a pair of Cooper is close to 1 nm. The same goes for the confinement of the electromagnetic field inside the superconducting part/layer of the superconducting wire.

The constituents of the superconducting part/layer of the superconducting wire, preferably Dy∈ Ndσ Snλ Seδ (∈, σ, λ, δ: positive or zero), and possible additive compounds, are chosen so that their atomic mass is high for adapt the interaction of phonons in the superconducting part/layer of the superconducting wire, particularly at high critical temperatures.

The constituents of the superconducting part/layer of the superconducting wire, preferably Dy∈ Ndσ Snλ Seδ (∈, σ, λ, δ: positive or zero), and possible additive compounds, are chosen for their antisymmetric wave functions with p and f layers available to favor the triplet states (7-tuples) of the wave function in the superconducting part/layer of the superconducting wire.

The constituents of the superconducting part/layer of the superconducting wire, preferably Dy∈ Ndσ Snλ Seδ (∈, σ, λ, δ: positive or zero), and possible additive compounds, are chosen for their entire core spins.

Fe, SC, Y, La, Ce, Pr, Sm, Gd, Tb, Ho, Er, Tm, Yb, Lu can also be associated in certain alloy compositions taking into account the value of the spin of the nucleus, the atomic mass and antisymmetric wave functions.

The superconducting part/layer of the superconducting wire can correspond to the following constitutive formula: M¹∈ M²σM³λ NM δ (∈, σ, λ, δ: positive or zero) in which M¹ M² M³each represent a metal such as for example Dy, Nd, Sn and NM represents a non-metal such as for example Se and possible additive compounds. The coefficients ∈, σ, λ, δ: positive or zero, allow different dosages and/or alloys to be made with possible additive compounds.

The superconducting part/layer of the superconducting wire has a crystal structure (basic topology in the form of 2D planes) which can promote the transport of electrons and holes in multiple planes (density of states depends linearly on energy) .

The superconducting part/layer of the superconducting wire has a crystal structure (basic topology in the form of 2D planes) which makes it possible to favor triplet states (7-tuples) of spins (parallel or antiparallel alignments).

The metallic constituents (metals) used in the superconducting part/layer of the superconducting wire are chosen from metals or alloys for which the electromagnetic confinement is the highest to favor interactions with Cooper pairs.

The metallic constituents (metals) used in the superconducting part/layer of the superconducting wire are chosen from metals or alloys for which the coherence length between the electrons allows the formation of Cooper pairs.

The metallic constituents (metals) used in the superconducting part/layer of the superconducting wire are chosen from metals or alloys to promote electromagnetic confinement.

The metallic constituents (metals) used in the superconducting part/layer of the superconducting wire are chosen from metals or alloys to promote the formation of Cooper pairs.

The metallic constituents (metals) used in the superconducting part/layer of the superconducting wire are chosen from metals or alloys to promote mechanical and chemical resistance, high current density, and temperature resistance.

The non-metal constituent used in the superconducting part/layer of the superconducting wire helps promote the formation of Cooper pairs.

The non-metal constituent used in the superconducting part/layer of the superconducting wire helps promote electromagnetic confinement.

The non-metal constituent used in the superconducting part/layer of the superconducting wire is chosen to promote mechanical and chemical resistance, high current density, and temperature resistance.

The superconducting part/layer of the elongated superconducting wire makes it possible to conduct an electric current in a main direction corresponding to the length of the element.

The superconducting part/layer of the superconducting wire may comprise a metal support or sheath which constitutes a conduction circuit parallel to that of the superconducting wire to carry current in the event of local loss of superconductivity.

The superconducting part/layer of the superconducting wire formed of a single row or of several juxtaposed rows in the form of a strand, particularly for a cable, can be surrounded by an external envelope ensuring electrical, mechanical and chemical protection. This envelope can be made of metal, for example the same metals and alloys as previously, or use a non-metallic envelope whose role will be limited to the mechanical and chemical protection of the assembly, for example an envelope made of synthetic resin.

The superconducting part/layer of the superconducting wire is made of crystals. These can be obtained by conventional processes using crystal growth techniques such as solid-solid transformation, growth by fusion, growth in solution by flux, growth in the vapor phase by thermal evaporation, electron bombardment or ablation. laser, vapor phase growth by chemical vapor deposition processes. It is also possible to use classic single crystal fabrication techniques such as zone fusion or epitaxy. The growth of these crystals means that they can develop in the form of needles or elongated lamellae.

According to one embodiment of the present invention, the superconducting wire (1000) is laminated.

According to one embodiment of the present invention, the superconducting wire (1000) is cylindrical.

According to one embodiment of the superconducting wire (1000), the thickness of the metal joints of the superconducting part/layer of the superconducting wire is between 1 and 1000 nm.

According to one embodiment, the superconducting wire (1000) has a width of between 0.6 and 0.8 µm.

According to one embodiment, the superconducting wire (1000) has a height of between 0.8 and 1.2 µm.

According to one embodiment of the present invention, the superconducting wire (1000) comprises at least, a first substrate (1101) formed of a conductive material, a first intermediate layer (1102) placed on the first substrate, and formed of a conductive material, a superconducting layer (1103), a second intermediate layer (1104) arranged on the superconducting layer and formed of a conductive material, a second substrate (1105) formed of a conductive material arranged on the second intermediate layer, a protective layer (1300). This stacking makes it possible, among other things, to limit thermal expansion constraints, to promote mechanical and chemical resistance, temperature resistance, high current density, and electromagnetic confinement.

According to one embodiment of the present invention, the superconducting wire (1000) comprises at least, a layer (1101) formed of a conductive material, an intermediate layer (1102) formed of a conductive material, a superconductive layer (1103 ), a protective layer (1300). This assembly makes it possible, among other things, to limit thermal expansion constraints, to promote mechanical and chemical resistance, temperature resistance, high current density, electromagnetic confinement. In this configuration, the layers have a cylindrical shape.

According to one embodiment of the superconducting wire (1000), the first substrate (1101) has an average height of 100 nm.

According to one embodiment of the superconducting wire (1000), the layer (1101) has an average thickness of 100 nm.

According to one embodiment of the superconducting wire (1000), the first intermediate layer (1102) has an average height of 100 nm.

According to one embodiment of the superconducting wire (1000), the intermediate layer (1102) has an average thickness of 100 nm.

According to one embodiment of the superconducting wire (1000), the superconducting layer (1103) has an average height of 400 nm.

According to one embodiment of the superconducting wire (1000), the superconducting layer (1103) has an average diameter of 400 nm.

According to one embodiment of the superconducting wire (1000), the second intermediate layer (1104) has an average height of 100 nm.

According to one embodiment of the superconducting wire (1000), the second substrate (1105) has an average height of 100 nm.

According to one embodiment of the superconducting wire (1000), the first substrate/layer (1101) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, and the current density.

According to one embodiment of the superconducting wire (1000), the first/intermediate layer (1102) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density, and to facilitate electromagnetic confinement and superconductivity in the superconducting layer (1103).

According to one embodiment of the superconducting wire (1000), the superconducting layer (1103) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density, and facilitates electromagnetic confinement and superconductivity.

According to one embodiment of the superconducting wire (1000), the second intermediate layer (1104) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density, and to facilitate electromagnetic confinement and superconductivity in the superconducting layer (1103).

According to one embodiment of the superconducting wire (1000), the second substrate (1105) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, and the current density.

According to one embodiment of the superconducting wire (1000), the protective layer (1300) has an average thickness of 200 nm.

According to one embodiment of the superconducting wire (1000), the protective layer (1300) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, and the current density.

According to one embodiment of the present invention, the first substrate (1101) is made of a conductive material. The first substrate includes a base layer and a conductive layer. The base layer and the conductive layer are made of a conductive material. The resistivity of the conductive layer is lower than the resistivity of the base layer. The conductive layer is disposed on the base layer. The base layer is made for example of stainless steel. The conductive layer is made, for example, of a metal alloy.

According to one embodiment of the present invention, the layer (1101) is made of a conductive material. The layer includes a base layer and a conductive layer. The base layer and the conductive layer are made of a conductive material. The resistivity of the conductive layer is lower than the resistivity of the base layer. The conductive layer is disposed on the base layer. The base layer is made for example of stainless steel. The conductive layer is made, for example, of a metal alloy. The layer (1101) is disposed on the intermediate layer (1102).

According to one embodiment of the present invention, the first intermediate layer (1102) is arranged on the first substrate (1101). More precisely, the first intermediate layer is placed on the first conductive layer. The first intermediate layer is made of a conductive material. The first intermediate layer is made for example of strontium titanate (SrTiO3) doped with niobium (Nb).

According to one embodiment of the present invention, the intermediate layer (1102) is arranged on the superconducting layer (1103). The intermediate layer is made of a conductive material. The intermediate layer is made for example of strontium titanate (SrTiO3) doped with niobium (Nb).

According to one embodiment of the present invention, the superconducting layer (1103) consists of a superconductor. The superconducting layer is made up of Dysprosium (Dy), Neodymium (Nd), Tin (Sn), Selenium (Se) such that the basic formula is Dy∈, Ndσ, Snλ, Seδ (∈, σ, λ, δ: positive or zero) and possible additive compounds. The coefficients ∈, σ, λ, δ: positive or zero, allow different dosages and/or alloys to be made with possible additive compounds.

According to one embodiment of the present invention, the superconducting layer of the superconducting wire (1103) is disposed on the first intermediate layer (1102).

According to one embodiment of the present invention, the superconducting layer of the superconducting wire (1103) is arranged under the intermediate layer (1102).

According to one embodiment of the present invention, the second intermediate layer (1104) is arranged on the superconducting layer (1103). The second intermediate layer is made of a conductive material. The second intermediate layer is made for example from strontium titanate (SrTiO3) doped with niobium (Nb).

According to one embodiment of the present invention, the second substrate (1105) is made of a conductive material. The second substrate includes a conductive layer and a base layer. The conductive layer and the base layer are made of a conductive material. The resistivity of the conductive layer is lower than the resistivity of the base layer. The base layer is disposed on the conductive layer. The base layer is made for example of stainless steel. The conductive layer is disposed on the second intermediate layer (1104). The conductive layer is made, for example, of a metal alloy.

According to one embodiment of the present invention, the protective layer (1300) is arranged so as to surround the periphery of the layers described, to protect the superconducting wire. More precisely, the protective layer is formed on the exterior surface of all the layers. The protective layer is made of a conductive material. The protective layer consists, for example, of silver or a silver alloy. The thickness of the protective layer is preferably equal to or less than 200 nm.

According to one embodiment of the present invention, the superconducting cable (2000) comprises several stranded superconducting wires (1000). Each superconducting wire is wound in a spiral around the central axis of a template which can for example be a cable made of aluminum or an alloy. The minimum value of the bending radius of each superconducting wire is 20mm or less.

Manufacturing process :

According to one embodiment of the present invention, the manufacturing process integrates chemical vapor deposition, atomic layer deposition, electron beam evaporation and/or magnetron sputtering processes. The superconducting substance is made of crystals. These can be obtained by conventional processes using crystal growth techniques such as solid-solid transformation, growth by fusion, growth in solution by flux, growth in the vapor phase by thermal evaporation, electron bombardment or ablation. laser, vapor phase growth by chemical vapor deposition processes.

Furthermore, by controlled deposition of tin in the gas phase on a solid substrate it is possible to form a monolayer of tin atoms with an insulating two-dimensional hexagonal structure. Depending on the type of substrate used, adhesion layers are necessary. These layers are applied by magnetron sputtering. The temperature depends on the thickness of the layer to be deposited. The adhesion layers have a thickness of less than 100 nm, which is why the temperature does not exceed 40 °C. The layer deposition is carried out in a pressure range of 8 × 10 ^-4 mbar to 5 × 10 ^-3 mbar. Argon is used as a spray gas. The base pressure is decisive for these layers.

First the first substrate is deposited. Secondly the first intermediate layer is deposited. Thirdly the superconducting layer is deposited. Fourthly the second intermediate layer is deposited. Fifth, the second substrate is deposited. Sixth, the protective layer is deposited by spraying. Furthermore, this process may comprise the preparation of granules of crystalline superconducting substance constituted by at least one row formed of at least one crystal of a superconducting substance having a preferred axis corresponding to the largest side of the crystalline mesh, then a coating at least two opposite faces of the granules, parallel to the preferred crystallographic axes of the crystals, with a film comprising at least one layer of metal or metal alloy; then an assembly of granules between them so as to form a row extending in the main direction of the element in which the granules are in contact by their opposite faces covered with the metal film and in which the privileged crystallographic axes of all the crystals make approximately the same angle with the main direction; and a heat treatment to join the granules together by metal joints formed from said films.

In the case of a cylindrical configuration, first the superconducting layer is deposited, secondly the intermediate layer is deposited, thirdly the conductive layer is deposited, fourthly the protective layer is deposited by sputtering.

It is also possible to use a matrix based on a silver alloy (AgCu, AgAu, AgMg, AgPd), which mainly improves the mechanical properties and increases the resistivity of the matrix, thus limiting losses. The whole is subjected to a series of processes such as stretching through an extrusion operation, rolling and heat treatments. A number of these filament-like tubes are stacked. This assembly is then extruded again to reach a certain diameter. This leads to a significant width to thickness ratio (around 10). The elementary grains of the compounds then appear in the form of platelets which can be observed under a microscope and which are easily aligned by a mechanical process. This process thus results in the production of a wire with a rectangular section.

The present invention has been described with reference to various embodiments. To the extent possible, one or more elements, components, constituents, structures, modules of the embodiments described may be combined, separated, interchanged, rearranged with one or more other elements, components, constituents, structures, modules of the embodiments without departing from the scope of the disclosed invention.

The present invention is not limited by the description of the different embodiments. Those skilled in the art can obtain other ways of implementation from the technical solutions of the present invention.

Claims (2)

Superconducting wire (1000) used at room temperature and ambient pressure, comprising,
a first substrate (1101) formed of a conductive material, the first substrate (1101) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density,
a first intermediate layer (1102) placed on the first substrate, and formed of a conductive material, the first intermediate layer (1102) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density, and facilitate electromagnetic confinement and superconductivity in the superconducting layer (1103),
a superconducting layer (1103), arranged on the first intermediate layer (1102), the superconducting layer (1103) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density, and facilitates electromagnetic confinement and the superconductivity, the superconducting layer is made up of Dysprosium (Dy), Neodymium (Nd), Tin (Sn), Selenium (Se) (∈, σ, λ, δ: positive or zero), the coefficients ∈, σ, λ, δ : positive or zero, allow different dosages and/or alloys to be made with possible additive compounds,
a second intermediate layer (1104) placed on the superconducting layer (1103) and formed of a conductive material, the second intermediate layer (1104) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density, and to facilitate electromagnetic confinement and superconductivity in the superconducting layer (1103),
a second substrate (1105) formed of a conductive material placed on the second intermediate layer (1104), the second substrate (1105) makes it possible to increase the mechanical and chemical resistance, the temperature resistance, the current density,
a protective layer (1300) formed on the outer surface so as to surround the periphery of the described layers, to protect the superconductor wire. Method for manufacturing a superconducting wire according to claim no. 1, Firstly the first substrate is deposited. Secondly the first intermediate layer is deposited. Thirdly the superconducting layer is deposited. Fourthly the second intermediate layer is deposited. Fifth, the second substrate is deposited. Sixth, the protective layer is deposited by spraying.