A system for powering a datacenter campus including a main direct current (DC) superconductor cable configured to receive direct current DC electrical power from an alternating current (AC) power grid through a AC-DC converter, a DC-DC hub connected to the main superconductor cable, and a plurality of secondary DC superconductor cables, wherein each secondary DC superconductor cable includes a first end electrically connected to the DC-DC hub and a second end electrically connected to server racks housed in a respective datacenter building of the datacenter campus.

A superconducting coil, includes a coil body around which a superconducting wire is wound; an electrode member which includes a first surface, a second surface, a base portion, and an extension portion, the first surface facing an outer peripheral surface of the coil body, the second surface being positioned to be opposite to the first surface, the base portion being solder-joined to the superconducting wire of the coil body on the first surface, the extension portion extending from the second surface to the outside of the coil body, and an electrode superconducting wire which extends from the second surface of the electrode member toward the extension portion, and is solder-joined to the base portion and the extension portion.

A connecting structure of an oxide superconducting wire includes a pair of oxide superconducting wires, tip surfaces of the pair of oxide superconducting wire being disposed to face to each other; a first surface-connecting superconducting wire configured to transit and connect the pair of oxide superconducting wires; and a second surface transit connector configured to transit and connect the pair of oxide superconducting wires, wherein tensile strength of joining sections between the second surface transit connector and the pair of oxide superconducting wires is higher than tensile strength of joining sections between the first surface-connecting superconducting wire and the pair of oxide superconducting wires.

A connecting structure of an oxide superconducting wire includes a pair of oxide superconducting wires, tip surfaces of the pair of oxide superconducting wire being disposed to face to each other; a first surface-connecting superconducting wire configured to transit and connect the pair of oxide superconducting wires; and a second surface transit connector configured to transit and connect the pair of oxide superconducting wires, wherein tensile strength of joining sections between the second surface transit connector and the pair of oxide superconducting wires is higher than tensile strength of joining sections between the first surface-connecting superconducting wire and the pair of oxide superconducting wires.

A method for creating electrical contact between a first superconductive strip conductor and a further electrical conductor element, wherein the first superconductive strip conductor is placed in flat contact against a first main surface of a reactive multilayer film in a contact area of the strip conductor, the second main surface, facing away from the first main surface, of the reactive multilayer film is placed in flat contact against the further electrical conductor element, and a permanent electrically conductive connection is formed between the first superconductive strip conductor and the further electrical conductor element by subsequently igniting an exothermic chemical reaction in the multilayer film. An electrical conductor assembly is able to be contacted using such a method.

A method for creating electrical contact between a first superconductive strip conductor and a further electrical conductor element, wherein the first superconductive strip conductor is placed in flat contact against a first main surface of a reactive multilayer film in a contact area of the strip conductor, the second main surface, facing away from the first main surface, of the reactive multilayer film is placed in flat contact against the further electrical conductor element, and a permanent electrically conductive connection is formed between the first superconductive strip conductor and the further electrical conductor element by subsequently igniting an exothermic chemical reaction in the multilayer film. An electrical conductor assembly is able to be contacted using such a method.

An electric circuit includes a first superconducting component, a second superconducting component, a first electrically-insulating component that thermally couples the first superconducting component and the second superconducting component such that heat produced in response to the first superconducting component transitioning to a non-superconducting state is transferred through the first electrically-insulating component to the second superconducting component, and a photon detector coupled to the first superconducting component. The photon detector is configured to output a first current to the first superconducting component upon detection of a threshold number of photons. The electric circuit further includes an output component coupled to the second superconducting component. The output component is configured to be responsive to a voltage drop across the second superconducting component.

An electric circuit includes a first superconducting component, a second superconducting component, a first electrically-insulating component that thermally couples the first superconducting component and the second superconducting component such that heat produced in response to the first superconducting component transitioning to a non-superconducting state is transferred through the first electrically-insulating component to the second superconducting component, and a photon detector coupled to the first superconducting component. The photon detector is configured to output a first current to the first superconducting component upon detection of a threshold number of photons. The electric circuit further includes an output component coupled to the second superconducting component. The output component is configured to be responsive to a voltage drop across the second superconducting component.

One embodiment includes a computer interconnect system. The system includes a first cable comprising a first superconducting signal line formed from a superconductor material to propagate at least one signal and a second cable comprising a second superconducting signal line formed from the superconductor material to propagate the respective at least one signal. The system also includes an interconnect structure configured to contact each of the first and second cable and comprising a third superconducting signal line formed from the superconductor material and configured to propagate the respective at least one signal between the respective first and second superconducting signal line. The system further includes at least one interconnect contact disposed on the first, second, and third at least one superconducting signal line at a contact portion between each of the at least one first and third superconducting signal lines and the at least second and third superconducting signal lines.

One embodiment includes a computer interconnect system. The system includes a first cable comprising a first superconducting signal line formed from a superconductor material to propagate at least one signal and a second cable comprising a second superconducting signal line formed from the superconductor material to propagate the respective at least one signal. The system also includes an interconnect structure configured to contact each of the first and second cable and comprising a third superconducting signal line formed from the superconductor material and configured to propagate the respective at least one signal between the respective first and second superconducting signal line. The system further includes at least one interconnect contact disposed on the first, second, and third at least one superconducting signal line at a contact portion between each of the at least one first and third superconducting signal lines and the at least second and third superconducting signal lines.