A semiconductor structure includes fins that have a 2D material, such as Graphene, upon at least the fin sidewalls. The thickness of the 2D material sidewall may be tuned to achieve desired finFET band gap control. Neighboring fins of the semiconductor structure form fin wells. The semiconductor structure may include a fin cap upon each fin and the 2D material is formed upon the sidewalls of the fin and the bottom surface of the fin wells. The semiconductor structure may include a well-plug at the bottom of the fin wells and the 2D material is formed upon the sidewalls and upper surface of the fins. The semiconductor structure may include both fin caps and well-plugs such that the 2D material is formed upon the sidewalls of the fins.

In a method for forming an integrated semiconductor device, a first inter-layer dielectric (ILD) layer is formed over a semiconductor device that includes a first transistor structure, a two-dimensional (2D) material layer is formed over and in contact with the first ILD layer, the 2D material layer is patterned to form a channel layer of a second transistor structure, a source electrode and a drain electrode of the second transistor structure are formed over the patterned 2D material layer and laterally spaced apart from each other, a gate dielectric layer of the second transistor structure is formed over the patterned 2D material layer, the source electrode and the drain electrode, and a gate electrode of the second transistor structure is formed over the gate dielectric layer and laterally between the source electrode and the drain electrode.

The present disclosure relates to an integrated circuit. In one implementation, the integrated circuit may include a semiconductor substrate; at least one source region comprising a first doped semiconductor material; at least one drain region comprising a second doped semiconductor material; at least one gate formed between the at least one source region and the at least one drain region; and a nanosheet formed between the semiconductor substrate and the at least one gate. The nanosheet may be configured as a routing channel for the at least one gate and may have a first region having a first width and a second region having a second width. The first width may be smaller than the second width.

A semiconductor device includes a substrate, a drift layer provided on an upper surface side of the substrate, a base layer provided on the upper surface side of the drift layer, an upper semiconductor layer provided on the upper surface side of the base layer, a first electrode provided on the upper surface of the substrate, a second electrode provided on a rear surface of the substrate, a trench extending to the drift layer from the upper surface of the substrate and a gate electrode provided inside the trench, wherein an inner side surface of the trench has a first surface and a second surface provided below the first surface, the second surface tilts inward of the trench with respect to the first surface, and an intersection point of the first surface and the second surface is provided below the base layer.

Some embodiments include an integrated assembly having a conductive structure, an annular structure extending through the conductive structure, and an active-material-structure lining an interior periphery of the annular structure. The annular structure includes dielectric material. The active-material-structure includes two-dimensional-material. Some embodiments include methods of forming integrated assemblies.

The present disclosure provides source/drain epitaxial structures and source/drain contacts wrapped with graphene layers in fin structures of FETs, and fabricating methods thereof. In some embodiments, a disclosed semiconductor device includes a fin structure on a substrate. The fin structure includes an epitaxial region. The semiconductor device further includes a metal contact above the epitaxial region, and a graphene film covering a top surface and sidewalls of the epitaxial region and covering a bottom surface and sidewalls of the metal contact.

Provided is a thin-film structure including a substrate, a nanocrystalline graphene layer provided on the substrate, and a two-dimensional material layer provided on the nanocrystalline graphene layer. The nucleation density of the two-dimensional material layer is 10.sup.9 ea/cm.sup.2 or more according to the nanocrystalline graphene layer, and accordingly, a two-dimensional material layer having an improved uniformity may be formed and a time duration for forming the two-dimensional material layer may be greatly decreased.

A semiconductor device and method of manufacturing using carbon nanotubes are provided. In embodiments a stack of nanotubes are formed and then a non-destructive removal process is utilized to reduce the thickness of the stack of nanotubes. A device such as a transistor may then be formed from the reduced stack of nanotubes.

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.

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.