A laminate contains a crystal substrate; a middle layer formed on a main surface of the crystal substrate, the middle layer comprising a mixture of an amorphous region in an amorphous phase and a crystal region in a crystal phase having a corundum structure mainly made of a first metal oxide; and a crystal layer formed on the middle layer and having a corundum structure mainly made of a second metal oxide, wherein the crystal region is an epitaxially grown layer from a crystal plane of the crystal substrate.

A vertical nanowire semiconductor device manufactured by a method of manufacturing a vertical nanowire semiconductor device is provided. The vertical nanowire semiconductor device includes a substrate, a first conductive layer in a source or drain area formed above the substrate, a semiconductor nanowire of a channel area vertically upright with respect to the substrate on the first conductive layer, wherein a crystal structure thereof is grown in <111> orientation, a second conductive layer of a drain or source area provided on the top of the semiconductor nanowire, a metal layer on the second conductive layer, a NiSi.sub.2 contact layer between the second conductive layer and the metal layer, a gate surrounding the channel area of the vertical nanowire, and a gate insulating layer located between the channel area and the gate.

A device includes a diode that includes a first group III-nitride (III-N) material and a transistor adjacent to the diode, where the transistor includes the first III-N material. The diode includes a second III-N material, a third III-N material between the first III-N material and the second III-N material, a first terminal including a metal in contact with the third III-N material, a second terminal coupled to the first terminal through the first group III-N material. The device further includes a transistor structure, adjacent to the diode structure. The transistor structure includes the first, second, and third III-N materials, a source and drain, a gate electrode and a gate dielectric between the gate electrode and each of the first, second and third III-N materials.

Provided is an electronic device including a semiconductor substrate, a single-crystal first transition metal oxide layer on the semiconductor substrate, and a single-crystal second transition metal oxide layer spaced apart from the semiconductor substrate with the single-crystal first transition metal oxide layer interposed therebetween. The first transition metal oxide layer and the second transition metal oxide layer are in contact with each other. The semiconductor substrate, the first transition metal oxide layer, and the second transition metal oxide layer include different materials from each other. The first transition metal oxide layer and the second transition metal oxide layer have the same crystal direction.

The present disclosure generally relates to bilayer metal dichalcogenides, to processes for forming bilayer metal dichalcogenides, and to uses of bilayer metal dichalcogenides in devices for quantum electronics. In an aspect, a device is provided. The device includes a gate electrode, a substrate disposed over at least a portion of the gate electrode, and a bottom layer including a first metal dichalcogenide, the bottom layer disposed over at least a portion of the substrate. The device further includes a top layer including a second metal dichalcogenide, the top layer disposed over at least a portion of the bottom layer, the first metal dichalcogenide and the second metal dichalcogenide being the same or different. The device further includes a source electrode and a drain electrode disposed over at least a portion of the top layer.

A method includes forming a semiconductor structure. The structure includes a first material, a blocking material, a second material in an amorphous form, and a third material in an amorphous form. The blocking material is disposed between the first material and the second material. At least the second material and the third material each comprise silicon and/or germanium. The structure is exposed to a temperature above a crystallization temperature of the third material and below a crystallization temperature of the second material. Semiconductor structures, memory devices, and systems are also disclosed.

Gate-all-around integrated circuit structures having germanium nanowire channel structures, and methods of fabricating gate-all-around integrated circuit structures having germanium nanowire channel structures, are described. For example, an integrated circuit structure includes a vertical arrangement of horizontal nanowires above a fin, each of the nanowires including germanium, and the fin including a defect modification layer on a first semiconductor layer, a second semiconductor layer on the defect modification layer, and a third semiconductor layer on the second semiconductor layer. A gate stack is around the vertical arrangement of horizontal nanowires. A first epitaxial source or drain structure is at a first end of the vertical arrangement of horizontal nanowires, and a second epitaxial source or drain structure is at a second end of the vertical arrangement of horizontal nanowires.

Provided are a method for preparing an InGaN-based epitaxial layer on a Si substrate (12), as well as a silicon-based InGaN epitaxial layer prepared by the method. The method may include the steps of: 1) directly growing a first InGaN-based layer (11) on a Si substrate (12); and 2) growing a second InGaN-based layer on the first InGaN-based layer (11).

Systems and methods disclosed and contemplated herein relate to manufacturing thin film semiconductors. Resulting thin film semiconductors are particularly suited for applications such as flexible optoelectronics and photovoltaic devices. Broadly, methods and techniques disclosed herein include high-temperature deposition techniques combined with lift-off in aqueous environments. These methods and techniques can be utilized to incorporate thin film semiconductors into substrates that have limited temperature tolerances.

A method of making an atomic layer nanoribbon that includes forming a double atomic layer ribbon having a first monolayer and a second monolayer on a surface of the first monolayer, wherein the first monolayer and the second monolayer each contains a transition metal dichalcogenide material, oxidizing at least a portion of the first monolayer to provide an oxidized portion, and removing the oxidized portion to provide an atomic layer nanoribbon of the transition metal dichalcogenide material. Also provided are double atomic layer ribbons, double atomic layer nanoribbons, and single atomic layer nanoribbons prepared according to the method.