A group III-N nanowire is disposed on a substrate. A longitudinal length of the nanowire is defined into a channel region of a first group III-N material, a source region electrically coupled with a first end of the channel region, and a drain region electrically coupled with a second end of the channel region. A second group III-N material on the first group III-N material serves as a charge inducing layer, and/or barrier layer on surfaces of nanowire. A gate insulator and/or gate conductor coaxially wraps completely around the nanowire within the channel region. Drain and source contacts may similarly coaxially wrap completely around the drain and source regions.

A first vertical field effect transistor (VFET) and a second VFET are formed on a substrate. The VFETs are parallel and adjacent to one another, and each comprises: a fin-shaped semiconductor; a lower source/drain (S/D) element; an upper S/D element; and a gate conductor. A portion of a gate conductor of the second VFET that is positioned over a lower S/D element of the second VFET is removed to leave a trench. An isolation spacer is formed to contact the gate conductor of the second VFET in a first portion of the trench. A lower S/D contact of the second VFET is formed on the lower S/D element of the second VFET in a second portion of the trench, a lower S/D contact of the first VFET is formed to a lower S/D element of the first VFET, and contacts are formed.

A first vertical field effect transistor (VFET) and a second VFET are formed on a substrate. The VFETs are parallel and adjacent to one another, and each comprises: a fin-shaped semiconductor; a lower source/drain (S/D) element; an upper S/D element; and a gate conductor. A portion of a gate conductor of the second VFET that is positioned over a lower S/D element of the second VFET is removed to leave a trench. An isolation spacer is formed to contact the gate conductor of the second VFET in a first portion of the trench. A lower S/D contact of the second VFET is formed on the lower S/D element of the second VFET in a second portion of the trench, a lower S/D contact of the first VFET is formed to a lower S/D element of the first VFET, and contacts are formed.

A method of making a carbon nanotube structure includes depositing a first oxide layer on a substrate and a second oxide layer on the first oxide layer; etching a trench through the second oxide layer; removing end portions of the first oxide layer and portions of the substrate beneath the end portions to form cavities in the substrate; depositing a metal in the cavities to form first body metal pads; disposing a carbon nanotube on the first body metal pads and the first oxide layer such that ends of the carbon nanotube contact each of the first body metal layers; depositing a metal to form second body metal pads on the first body metal pads at the ends of the carbon nanotube; and etching to release the carbon nanotube, first body metal pads, and second body metal pads from the substrate, first oxide layer, and second oxide layer.

The present disclosure relates to a nano-scale transistor. The nano-scale transistor includes a source electrode, a drain electrode, a gate electrode and a nano-heterostructure. The nano-heterostructure is electrically coupled with the source electrode and the drain electrode. The gate electrode is insulated from the nano-heterostructure, the source electrode and the drain electrode via an insulating layer. The nano-heterostructure includes a first carbon nanotube, a second carbon nanotube and a semiconductor layer. The semiconductor layer includes a first surface and a second surface opposite to the first surface. The first carbon nanotube is located on the first surface, the second carbon nanotube is located on the second surface.

The present disclosure relates to a method for making nanoscale heterostructure. The method includes: providing a support and forming a first carbon nanotube layer on the support, and the first carbon nanotube layer comprises a plurality of first source carbon nanotubes; forming a semiconductor layer on the first carbon nanotube layer; covering a second carbon nanotube layer on the semiconductor layer, and the second carbon nanotube layer comprises a plurality of second source carbon nanotubes; finding and labeling a first carbon nanotube in the first carbon nanotube layer and a second carbon nanotube in the second carbon nanotube layer; removing the plurality of first source carbon nanotubes and the plurality of second source carbon nanotubes; and annealing the multilayer structure.

A group III-N nanowire is disposed on a substrate. A longitudinal length of the nanowire is defined into a channel region of a first group III-N material, a source region electrically coupled with a first end of the channel region, and a drain region electrically coupled with a second end of the channel region. A second group III-N material on the first group III-N material serves as a charge inducing layer, and/or barrier layer on surfaces of nanowire. A gate insulator and/or gate conductor coaxially wraps completely around the nanowire within the channel region. Drain and source contacts may similarly coaxially wrap completely around the drain and source regions.

The present disclosure relates to semiconductor based Josephson junctions and their applications within the field of quantum computing, in particular a tuneable Josephson junction device has been used to construct a gateable transmon qubit. One embodiment relates to a Josephson junction comprising an elongated hybrid nanostructure comprising superconductor and semiconductor materials and a weak link, wherein the weak link is formed by a semiconductor segment of the elongated hybrid nanostructure wherein the superconductor material has been removed to provide a semiconductor weak link.

In a method of manufacturing a semiconductor device, a support layer is formed over a substrate. A patterned semiconductor layer made of a first semiconductor material is formed over the support layer. A part of the support layer under a part of the semiconductor layer is removed, thereby forming a semiconductor wire. A semiconductor shell layer made of a second semiconductor material different from the first semiconductor material is formed around the semiconductor wire.

An alternating stack of layers of a first epitaxial semiconductor material and a second epitaxial semiconductor material is formed on a substrate. A fin stack is formed by patterning the alternating stack into a shape of a fin having a parallel pair of vertical sidewalls. After formation of a disposable gate structure and an optional gate spacer, raised active regions can be formed on end portions of the fin stack. A planarization dielectric layer is formed, and the disposable gate structure is subsequently removed to form a gate cavity. A crystallographic etch is performed on the first epitaxial semiconductor material to form vertically separated pairs of an upright triangular semiconductor nanowire and an inverted triangular semiconductor nanowire. Portions of the epitaxial disposable material are subsequently removed. After an optional anneal, the gate cavity is filled with a gate dielectric and a gate electrode to form a field effect transistor.