The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming a replacement channel composed of a III-V compound semiconductor material in a doped layer of a III-V compound semiconductor substrate. The replacement channel may be formed by removing a portion of the doped layer located directly below a dummy gate stack that has been removed. A III-V compound semiconductor material may be grown in the removed the portion to form the replacement channel and a gate stack may be formed on the replacement channel.

A heterojunction structure of semiconductor material, for a high electron mobility transistor includes a substrate, a buffer layer, arranged on the substrate, of a large bandgap semiconductor material, based on a nitride from column III, where the buffer layer is not intentionally doped with n-type carriers, a barrier layer arranged above the buffer layer, of a large bandgap semiconductor material based on a nitride from column III, where the width of the bandgap of the barrier layer is less than the width of the bandgap of the buffer layer. The heterojunction structure additionally comprises an intentionally doped area, of a material based on a nitride from column III identical to the material of the buffer layer, in a plane parallel to the plane of the substrate and a predefined thickness along a direction orthogonal to the plane of the substrate, where the area is comprised in the buffer layer.

Various embodiments disclose a method for fabricating vertical transistors. In one embodiment, a structure is formed comprising at least a first substrate, an insulator layer on the substrate, a first doped layer on the insulator layer, at least one fin structure in contact with the doped layer, a dielectric layer surrounding a portion of the fin structure, a gate layer on the dielectric layer, a second doped layer in contact with the fin structure, a first contact area in contact with the second doped layer, and at least a first interconnect in contact with the first contact area. The structure is flipped bonded to a second substrate. The first substrate and the insulator layer are removed to expose the first doped layer. A second contact area is formed in contact with the first doped layer. At least a second interconnect is formed in contact with the second contact area.

An integrated device is provided. The integrated device includes a substrate having a doped upper surface section and an insulator to define first and second substrate regions on opposite sides thereof. Vertical transistors are operably arranged on the doped upper surface section at the first substrate region. P-I-N diodes are operably arranged on the doped upper surface section at the second substrate region.

A method of forming a high electron mobility transistor (HEMT) includes forming a second III-V compound layer on a first III-V compound layer, forming a source feature and a drain feature on the second III-v compound layer, depositing a p-type layer on a portion of the second III-V compound layer between the source feature and the drain feature, and forming a gate electrode on the p-type layer. A carrier channel is located between the first III-V compound layer and the second III-V compound layer.

Structures and fabrication methods for a vertical-transport field-effect transistor. A plurality of pillars comprised of a semiconductor material are formed. First and second gate structures are located along a length of the pillars. The second gate structure is vertically spaced along the length of the pillars relative to the first gate structure. The first and second gate structures are each associated with a channel defined in the pillars.

The present disclosure provides a method for manufacturing an array substrate, an array substrate and a display device. The method includes: forming a gate line, a gate electrode and an insulating layer which covers the gate line and the gate electrode on a first surface of a substrate; forming a semiconductive film on the insulating layer; patterning the semiconductive film using the gate electrode and the gate line as a mask, so as to form an source semiconductive layer at a region where the gate line and the gate electrode are located; and manufacturing a target semiconductive layer using the source semiconductive layer.

A semiconductor structure and a manufacturing method are provided. The semiconductor structure includes a substrate, conductive layers, insulating layers, a memory structure including first memory structure clusters and second memory structure clusters, isolation trenches, and common source trenches. The conductive layers and the insulating layers are interlaced and stacked on the substrate. Each first memory structure cluster include first memory structures and each first memory structure cluster include second memory structures. The first and second memory structures penetrate the conductive layers and the insulating layers. Each isolation trench is formed between a first memory structure cluster and a second memory structure cluster. The isolation trenches span horizontally on the substrate in a discontinuous manner separated by gaps. Common source trenches are formed on the substrate that run substantially parallel with the isolation trenches.

There are disclosed herein various implementations of a semiconductor component with a multi-layered nucleation body and method for its fabrication. The semiconductor component includes a substrate, a nucleation body situated over the substrate, and a group III-V semiconductor device situated over the nucleation body. The nucleation body includes a bottom layer formed at a low growth temperature, and a top layer formed at a high growth temperature. The nucleation body also includes an intermediate layer that is formed substantially continuously using a varying intermediate growth temperature.

Semiconductor devices having vertical FET (field effect transistor) devices with metallic source/drain regions are provided, as well as methods for fabricating such vertical FET devices. For example, a semiconductor device includes a first source/drain region formed on a semiconductor substrate, a vertical semiconductor fin formed on the first source/drain region, a second source/drain region formed on an upper surface of the vertical semiconductor fin, a gate structure formed on a sidewall surface of the vertical semiconductor fin, and an insulating material that encapsulates the vertical semiconductor fin and the gate structure. The first source/drain region comprises a metallic layer and at least a first epitaxial semiconductor layer. For example, the metallic layer of the first source/drain region comprises a metal-semiconductor alloy such as silicide.