An integrated circuit (IC) structure with a nanowire power switch device and a method of forming the IC structure are disclosed. The method includes forming a first layer of metal lines of a first back end of line (BEOL) interconnect structure and forming a semiconductor nanowire structure on a first metal line of the first layer of metal lines. The BEOL interconnect structure is formed on a front end of line (FEOL) device layer having multiple active devices. The method further includes forming a first dielectric layer wrapped around the semiconductor nanowire structure, forming a metal layer on the dielectric layer and on a second metal line of the first layer of metal lines, and forming a second layer of metal lines of a second BEOL interconnect structure on the semiconductor nanowire structure. The first and second metal lines are electrically isolated from each other.

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 method of fabricating a semiconductor integrated circuit (IC) is disclosed. The method includes providing a substrate and depositing a conductive layer on the substrate. A patterned hard mask and a catalyst layer are formed on the conductive layer. The method further includes growing a plurality of carbon nanotubes (CNTs) from the catalyst layer and etching the conductive layer by using the CNTs and the patterned hard mask as an etching mask to form metal features.

An integrated circuit (IC) structure with a nanowire power switch device and a method of forming the IC structure are disclosed. The method includes forming a first layer of metal lines of a first back end of line (BEOL) interconnect structure and forming a semiconductor nanowire structure on a first metal line of the first layer of metal lines. The BEOL interconnect structure is formed on a front end of line (FEOL) device layer having multiple active devices. The method further includes forming a first dielectric layer wrapped around the semiconductor nanowire structure, forming a metal layer on the dielectric layer and on a second metal line of the first layer of metal lines, and forming a second layer of metal lines of a second BEOL interconnect structure on the semiconductor nanowire structure. The first and second metal lines are electrically isolated from each other.

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.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate, a gate stack positioned on the substrate, a plurality of programmable contacts positioned on the gate stack, a pair of heavily-doped regions positioned adjacent to two sides of the gate stack and in the substrate, and a plurality of first contacts positioned on the pair of heavily-doped regions. A width of the plurality of programmable contacts is less than a width of the plurality of first contacts.

An electrical interconnection. In order to efficiently conduct electrical current in small-scale structures and at high frequencies, the electrical interconnection has a channel portion which includes at least one channel layer made of a weak topological insulator material and having a top surface with a plurality of grooves extending from a first terminal to a second terminal of the electrical interconnection, wherein the top surface and a bottom surface of each groove are insulating, whereas each side surface of each groove includes a conducting zone with a pair of topologically protected one-dimensional electron channels.

In some examples, a semiconductor package comprises a semiconductor die having a first surface and a second surface opposing the first surface. The package comprises an orifice extending through a thickness of the semiconductor die from the first surface to the second surface. The package comprises a set of metallic nanowires positioned within the orifice and extending through the thickness of the semiconductor die from the first surface to the second surface.

A method of forming a structure comprises forming a pattern of self-assembled nucleic acids over a material. The pattern of self-assembled nucleic acids is exposed to at least one repair enzyme to repair defects in the pattern. The repaired pattern of self-assembled nucleic acids is transferred to the material to form features therein. A method of decreasing defect density in self-assembled nucleic acids is also disclosed. Self-assembled nucleic acids exhibiting an initial defect density are formed over at least a portion of a material and the self-assembled nucleic acids are exposed to at least one repair enzyme to repair defects in the self-assembled nucleic acids. Additional methods are also disclosed.

A device relates to a semiconductor device. The semiconductor device includes a narrow-line bamboo microstructure integrated within a metal layer of the semiconductor device and a narrow-line polycrystalline microstructure. The narrow-line polycrystalline microstructure is integrated within the same metal layer as the narrow-line bamboo microstructure.