A method for producing a semiconductor power device includes forming a gate trench from a surface of the semiconductor layer toward an inside thereof. A first insulation film is formed on the inner surface of the gate trench. The method also includes removing a part on a bottom surface of the gate trench in the first insulation film. A second insulation film having a dielectric constant higher than SiO2 is formed in such a way as to cover the bottom surface of the gate trench exposed by removing the first insulation film.

In a method for forming an integrated semiconductor device, a first transistor over is formed on a substrate; an inter-layer dielectric (ILD) layer is deposited over the first transistor; a gate conductive layer is deposited over the ILD layer; a gate dielectric layer is deposited over the gate conductive layer; the gate dielectric layer and the gate conductive layer are etched to form a gate stack; and a 2D material layer that has a first portion extending along a top surface and sidewalls of the gate stack and a second portion extending along a top surface of the ILD layer.

Disclosed is a high-quality and high-functional graphene-based TFT, including: a gate electrode, a gate insulating layer disposed on the gate electrode; an active layer including a nitrogen-doped graphene layer, on which disposed in a partial region of the gate insulating layer; a first electrode disposed on a region of one side of the active layer; and a second electrode disposed on a region of the other side of the active layer. The present invention allows obtaining the TFT having excellent characteristics by directly growing graphene on a Ti layer, implementing damages with remote plasma, and doping with nitrogen gas to fabricate a graphene active layer.

One device disclosed herein includes, among other things, first and second conductive features embedded in a first dielectric layer, a cap layer positioned above the first dielectric layer, a ballistic transport material contacting the first conductive member and positioned above a portion of the first dielectric layer, and first and second contacts contacting the first and second conductive features.

A finFET device that includes a substrate and at least one semiconductor fin extending from the substrate. The fin may include a plurality of wide portions comprising a first semiconductor material and one or more narrow portions. The one or more narrow portions have a second width less than the first width of the wide portions. Each of the one or more narrow portions separates two of the plurality of wide portions from one another such that the plurality of wide portions and the one or more narrow portions are arranged alternatingly in a substantially vertical direction that is substantially perpendicular with a surface of the substrate. The fin may also include a channel layer covering sidewalls of the plurality of wide portions and a sidewall of the one or more narrow portions.

A doped diamond semiconductor and method of production using a laser is disclosed herein. As disclosed, a dopant and/or a diamond or sapphire seed material may be added to a graphite based ablative layer positioned below a confinement layer, the ablative layer also being graphite based and positioned above a backing layer, to promote formation of diamond particles having desirable semiconductor properties via the action of a laser beam upon the ablative layer. Dopants may be incorporated into the process to activate the reaction sought to produce a material useful in production of a doped semiconductor or a doped conductor suitable for the purpose of modulating the electrical, thermal or quantum properties of the material produced. As disclosed, the diamond particles formed by either the machine or method of confined pulsed laser deposition disclosed may be arranged as semiconductors, electrical components, thermal components, quantum components and/or integrated circuits.

A field effect transistor (FET), a method of fabricating a field effect transistor, and an electronic device, the field effect transistor comprises: a source and a drain, the source being made of a first graphene film; a channel disposed between the source and the drain, and comprising a laminate of a second graphene film and a material layer having semiconductor properties, the second graphene film being formed of bilayer graphene; and a gate disposed on the laminate and electrically insulated from the laminate.

A field effect transistor (FET), a method of fabricating the field effect transistor, and an electronic device are provided. The field effect transistor comprises: a source and a drain, the source being made of a Dirac material (103); a channel disposed between the source and the drain, and doped opposite to the source; and a gate (106) disposed on the channel and electrically insulated from the channel.

The present disclosure provides a thin film transistor and an array substrate. The thin film transistor includes a source, a drain, and an active layer, and the thin film transistor further includes a blocking layer between the active layer and the source and/or the drain. The present disclosure can reduce the off-state current of the thin film transistor and suppress the bipolar effect.

A transistor includes a gate electrode with multiple metals distributed along the width of the gate electrode. Each of the metals in the gate electrode has different work functions. Such a compound gate provides higher linearity when, e.g., operated as a radio frequency transistor.