In accordance with an embodiment, a method includes switching on a transistor device by generating a first conducting channel by driving a first gate electrode and, before generating the first conducting channel, generating a second conducting channel by driving a second gate electrode, wherein the second gate electrode is adjacent the first gate electrode in a current flow direction of the transistor device.

A method of forming a vertical transistor includes forming at least one fin on stacked layers. The stacked layers include a substrate, a doped silicon layer, and an intrinsic layer interposed between the pair of fins and the substrate. The method further includes forming a spacer hardmask over the pair of fins, and forming a bottom spacer. Forming the bottom spacer includes selective oxidation of the SiGe layer.

Embodiments herein describe techniques for a semiconductor device including a capacitor and a transistor above the capacitor. A contact electrode may be shared between the capacitor and the transistor. The capacitor includes a first plate above a substrate, and the shared contact electrode above the first plate and separated from the first plate by a capacitor dielectric layer, where the shared contact electrode acts as a second plate for the capacitor. The transistor includes a gate electrode above the substrate and above the capacitor; a channel layer separated from the gate electrode by a gate dielectric layer, and in contact with the shared contact electrode; and a source electrode above the channel layer, separated from the gate electrode by the gate dielectric layer, and in contact with the channel layer. The shared contact electrode acts as a drain electrode of the transistor. Other embodiments may be described and/or claimed.

A vertical field effect transistor. The vertical field effect transistor includes a trench structure having a first side and a second side opposite the first side. A field effect transistor (FET) channel is formed at the first side, and the second side is free of a FET channel. The FET channel includes a gallium nitride (GaN) region and an aluminum gallium nitride (AlGaN) region adjacent thereto. The GaN region includes a p-conductive first region and a second region formed thereon. The vertical field effect transistor also includes a source electrode that is electroconductively connected to the p-conductive first region of the GaN region and to the AlGaN region.

A method of fabricating a vertical fin-based field effect transistor (FET) includes providing a semiconductor substrate having a first surface and a second surface, the semiconductor substrate having a first conductivity type, epitaxially growing a first semiconductor layer on the first surface of the semiconductor substrate, the first semiconductor layer having the first conductivity type and including a drift layer and a graded doping layer on the drift layer, and epitaxially growing a second semiconductor layer having the first conductivity type on the graded doping layer. The method also includes forming a metal compound layer on the second semiconductor layer, forming a patterned hard mask layer on the metal compound layer, and etching the metal compound layer and the second semiconductor layer using the patterned hard mask layer as a mask exposing a surface of the graded doping layer to form a plurality of fins surrounded by a trench.

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.

A semiconductor structure, device, or N-polar Ill-nitride vertical field effect transistor. The structure, device, or transistor includes a current blocking layer and an aperture region. The current blocking layer and aperture region are comprised of the same material The current blocking layer and aperture region are formed by polarization engineering and not doping or implantation. A method of making a semiconductor structure, device, or Ill-nitride vertical transistor. The method includes obtaining, growing, or forming a functional bilayer comprising a barrier layer and a two-dimensional electron gas-containing layer. The functional bilayer is not formed via a regrowth step.

A semiconductor arrangement and methods of formation are provided. A semiconductor arrangement includes a semiconductor column on a buffer layer over a substrate. The buffer layer comprises a conductive material. Both a first end of the semiconductor column and a bottom contact are connected to a buffer layer such that the first end of the semiconductor column and the bottom contact are connected to one another through the buffer layer, which reduces a contact resistance between the semiconductor column and the bottom contact. A second end of the semiconductor column is connected to a top contact. In some embodiments, the first end of the semiconductor column corresponds to a source or drain of a transistor and the second end corresponds to the drain or source of the transistor.

A vertical JFET is provided. The JFET is mixed with lateral channel structure and p-GaN gate structure. The JFET has an improved barrier layer for p-GaN block layer and enhanced Ohmic contact with source. In one embodiment, regrowth of lateral channel is provided so that counter doping surface Mg will be buried. In another embodiment, a dielectric layer is provided to protect p-type block layer during the processing, and later make Ohmic source and p-type block layer. Method of a barrier regrown layer for enhanced lateral channel performance is provided where a regrown barrier layer is deposited over the drift layer. The barrier regrown layer is an anti-p-doping layer. Method of a patterned regrowth for enhanced Ohmic contact is provided where a patterned masked is used for the regrowth.

A device includes a substrate, a first electrode on the substrate, an insulating pattern on the substrate, a second electrode on an upper end of the insulating pattern, a two-dimensional (2D) material layer on a side surface of the insulating pattern, a gate insulating layer covering the 2D material layer, and a gate electrode contacting the gate insulting layer. The insulating pattern extends from the first electrode in a direction substantially vertical to the substrate. The 2D material layer includes at least one atomic layer of a 2D material that is substantially parallel to the side surface of the insulating pattern.