A device includes a substrate and insulation regions over a portion of the substrate. A first semiconductor region is between the insulation regions and having a first conduction band. A second semiconductor region is over and adjoining the first semiconductor region, wherein the second semiconductor region includes an upper portion higher than top surfaces of the insulation regions to form a semiconductor fin. The second semiconductor region also includes a wide portion and a narrow portion over the wide portion, wherein the narrow portion is narrower than the wide portion. The semiconductor fin has a tensile strain and has a second conduction band lower than the first conduction band. A third semiconductor region is over and adjoining a top surface and sidewalls of the semiconductor fin, wherein the third semiconductor region has a third conduction band higher than the second conduction band.

A nitride semiconductor device includes: a substrate; a first nitride semiconductor layer (1) located over the substrate; a second nitride semiconductor layer (2) located over the first nitride semiconductor layer (1), having a larger band gap than the first nitride semiconductor layer (1), and having a recess (11) penetrating into the first nitride semiconductor layer (1); and a third nitride semiconductor layer (12) continuously covering the second nitride semiconductor layer (2) and the recess (11), and having a larger band gap than the first nitride semiconductor layer (1); a gate electrode (5) located above a portion of the third nitride semiconductor layer (12) over the recess (11); and a first ohmic electrode (4a) and a second ohmic electrode (4b) located on opposite sides of the gate electrode (5).

The disclosure describes the use of strain to enhance the properties of p- and n-materials so as to improve the performance of III-N electronic and optoelectronic devices. In one example, transistor devices include a channel aligned along uniaxially strained or relaxed directions of the III-nitride material in the channel. Strain is introduced using buffer layers or source and drain regions of different composition

A heterojunction semiconductor device with a low on-resistance includes a metal drain electrode, a substrate, and a buffer layer. A current blocking layer is arranged in the buffer layer, a gate structure is arranged on the buffer layer, and the gate structure comprises a metal gate electrode, GaN pillars and AlGaN layers, wherein a metal source electrode is arranged above the metal gate electrode; and the current blocking layer comprises multiple levels of current blocking layers, the centers of symmetry of the layers are collinear, and annular inner openings of the current blocking layers at all levels gradually become smaller from top to bottom. The AlGaN layers and the GaN pillars are distributed in a honeycomb above the buffer layer.

A semiconductor device and a method of manufacture are provided. A substrate has a dielectric layer formed thereon. A three-dimensional feature, such as a trench or a fin, is formed in the dielectric layer. A two-dimensional layer, such as a layer (or multilayer) of graphene, transition metal dichalcogenides (TMDs), or boron nitride (BN), is formed over sidewalls of the feature. The two-dimensional layer may also extend along horizontal surfaces, such as along a bottom of the trench or along horizontal surfaces of the dielectric layer extending away from the three-dimensional feature. A gate dielectric layer is formed over the two-dimensional layer and a gate electrode is formed over the gate dielectric layer. Source/drain contacts are electrically coupled to the two-dimensional layer on opposing sides of the gate electrode.

A method for producing a solid state device, including forming a first dielectric layer over an epitaxial layer at least partially covering the a silicon substrate and depositing a photoresist material there-over, removing a predetermined portion first dielectric layer to define an exposed portion, implanting dopants into the exposed portion to define a doped portion, preferentially removing silicon from the exposed portion to generate trenches having V-shaped cross-sections and having first and second angled sidewalls defining the V-shaped cross-section, wherein each angled sidewall defining the V-shaped cross-section is a silicon face having a in orientation, and forming a 2DEG on at least one sidewall.

There is provided a method of manufacturing a non-volatile memory device including: alternatively stacking a plurality of insulating layers and a plurality of conductive layers on a top surface of a substrate; forming an opening that exposes the top surface of the substrate and lateral surfaces of the insulating layers and the conductive layers; forming an anti-oxidation layer on at least the exposed lateral surfaces of the conductive layers; forming a gate dielectric layer on the anti-oxidation layer, the gate dielectric layer including a blocking layer, an electric charge storage layer, and a tunneling layer that are sequentially formed on the anti-oxidation layer; and forming a channel region on the tunneling layer.

Trenched vertical power field-effect transistors with improved on-resistance and/or breakdown voltage are fabricated. In one or more embodiments, the modulation of the current flow of the transistor occurs in the lateral channel, whereas the voltage is predominantly held in the vertical direction in the off-state. When the device is in the on-state, the current is channeled through an aperture in a current-blocking region after it flows under a gate region into the drift region. In another embodiment, a novel vertical power low-loss semiconductor multi-junction device in III-nitride and non-III-nitride material system is provided. One or more multi-junction device embodiments aim at providing enhancement mode (normally-off) operation alongside ultra-low on resistance and high breakdown voltage.

The present invention provides a method for forming a quantum well device having high mobility and high breakdown voltage with enhanced performance and reliability. A method for fabrication of a Vertical Cylindrical GaN Quantum Well Power Transistor for high power application is disclosed. Compared with the prior art, the method of forming a quantum well device disclosed in the present invention has the beneficial effects of high mobility and high breakdown voltage with better performance and reliability.

An integrated circuit includes a substrate supporting a transistor having a source region and a drain region. A high dopant concentration delta-doped layer is present on the source region and drain region of the transistor. A set of contacts extend through a pre-metal dielectric layer covering the transistor. A silicide region is provided at a bottom of the set of contacts. The silicide region is formed by a salicidation reaction between a metal present at the bottom of the contact and the high dopant concentration delta-doped layer on the source region and drain region of the transistor.