A quantum semiconductor device includes a qubit chip; an interposer chip, with a handler, including a through-silicon-via (TSV) coupled to a first side of the qubit chip. A multi-level wiring (MLW) layer contacts an underside of the interposer chip and coupling to the top side of the handler, the TSV facilitates an electrical signal connection between the MLW layer, a topside of the interposer chip and the qubit chip, wherein structure of the device mitigates signal cross-talk across respective lines of the MLW layer.

The subject disclosure is directed towards layered substrate structures with aligned optical access to electrical devices formed thereon for laser processing and electrical device tuning. According to an embodiment, a layered substrate structure is provided that comprises an optical substrate having a first surface and a second surface and a patterned bonding layer formed on the second surface that comprises a bonding region and an open region, wherein the open region exposes a portion of the second surface. The layered substrate structure further comprises a device chip bonded to the patterned bonding layer via the bonding region and comprising at least one electrical component aligned with the optical substrate and the open region. The at least one electrical component can include for example, a thin film wire, an air bridge, a qubit, an electrode, a capacitor or a resonator.

A quantum mechanical circuit includes a substrate; a first electrical conductor and a second electrical conductor provided on the substrate and spaced apart to provide a gap therebetween; and a third electrical conductor to electrically connect the first electrical conductor and the second electrical conductor. The third electrical conductor is a poor thermal conductor.

A package includes a metal plate and a carrier substrate mounted on the top surface thereof, which includes one or more superconducting chips mounted on the carrier substrate or configured to receive the one or more chips mounted thereon. The carrier substrate and the plate are sandwiched between the planar portions of a first and second magnetic shield structure, at least the first structure including a planar portion and a receptacle-shaped shell portion arranged above and around the chip location. The package includes one or more pillars formed of a magnetic shielding material which are clamped between the planar portions of the shield structures, wherein the one or more pillars are penetrating the carrier substrate and the metal support plate, and wherein the one or more pillars are in physical contact with both of the planar portions.

A package includes a metal plate and a carrier substrate mounted on the top surface thereof, which includes one or more superconducting chips mounted on the carrier substrate or configured to receive the one or more chips mounted thereon. The carrier substrate and the plate are sandwiched between the planar portions of a first and second magnetic shield structure, at least the first structure including a planar portion and a receptacle-shaped shell portion arranged above and around the chip location. The package includes one or more pillars formed of a magnetic shielding material which are clamped between the planar portions of the shield structures, wherein the one or more pillars are penetrating the carrier substrate and the metal support plate, and wherein the one or more pillars are in physical contact with both of the planar portions.

A quantum Hall resistance apparatus is to improve resistance standards and includes a substrate, a graphene epitaxially grown on the substrate and having a plurality of first contact patterns at edges of the graphene, a plurality of contacts, each including a second contact pattern and configured to connect to a corresponding first contact pattern, and a protective layer configured to protect the graphene and to increase adherence between the first contact patterns and the second contact patterns. The contacts become a superconductor at a temperature lower than or equal to a predetermined temperature and under up to a predetermined magnetic flux density.

Devices, systems, methods, computer-implemented methods, apparatus, and/or computer program products that can facilitate a suspended Majorana fermion device comprising an ion implant defined nanorod in a semiconducting device are provided. According to an embodiment, a quantum computing device can comprise a Majorana fermion device coupled to an ion implanted region. The quantum computing device can further comprise an encapsulation film coupled to the ion implanted region and a substrate layer. The encapsulation film suspends the Majorana fermion device in the quantum computing device.

A method of producing a quantum circuit includes forming a mask on a substrate to cover a first portion of the substrate, implanting a second portion of the substrate with ions, and removing the mask, thereby providing a nanowire. The method further includes forming a first lead and a second lead, the first lead and the second lead each partially overlapping the nanowire. In operation, a portion of the nanowire between the first and second leads forms a quantum dot, thereby providing a quantum dot Josephson junction. The method further includes forming a third lead and a fourth lead, one of the third and fourth leads partially overlapping the nanowire, wherein the third lead is separated from the fourth lead by a dielectric layer, thereby providing a Dolan bridge Josephson junction. The nanowire is configured to connect the quantum dot Josephson junction and the Dolan bridge Josephson junction in series.

A quantum device includes a chip including a superconducting circuit, a first wiring substrate, a second wiring substrate, first connection portions connecting the chip and a wiring layer on a first surface of the first wiring substrate and second connection portions connecting the second wiring substrate and a wiring layer on a second surface of the first wiring substrate, wherein one or more second connection portions arranged in a first row as viewed from the edge of the first substrate are provided at positions corresponding respectively to one or more of the first connection portions arranged in a first row as viewed from the edge and are arranged closer to the edge than the first connection portions arranged in the first row.

A quantum device includes a chip including a superconducting circuit, a first wiring substrate, a second wiring substrate, first connection portions connecting the chip and a wiring layer on a first surface of the first wiring substrate and second connection portions connecting the second wiring substrate and a wiring layer on a second surface of the first wiring substrate, wherein one or more second connection portions arranged in a first row as viewed from the edge of the first substrate are provided at positions corresponding respectively to one or more of the first connection portions arranged in a first row as viewed from the edge and are arranged closer to the edge than the first connection portions arranged in the first row.