An exemplary method of forming a semiconductor device includes forming, in a substrate, an active region protruding vertically from a major surface of the substrate, the active region including a semiconductor source-drain (S/D) region and a first 3-D channel structure, the S/D region physically contacting the first 3-D channel structure, and forming an opening extending into the S/D region, the opening having a depth greater than half of a height of the first 3-D channel structure; and forming a metallic plug in the opening, the metallic plug making electrical contact with the S/D region.

A method includes providing a structure having a substrate and first and second semiconductor layers alternately stacked one over another above the substrate, etching the first and the second semiconductor layers to form a first continuous ring in a seal ring region of the structure, and forming an isolation structure adjacent the first continuous ring in the seal ring region. The method further includes forming a dummy gate structure that is disposed directly above the first continuous ring and completely within a boundary of the first continuous ring from a top view, growing first and second epitaxial features sandwiching the dummy gate structure, removing the dummy gate structure, resulting in a gate trench that exposes a topmost layer of the first semiconductor layers and does not expose side surfaces of the first and second semiconductor layers, and depositing a gate structure in the gate trench.

Provided are an organic thin film transistor, an organic semiconductor film, a compound, an organic thin film transistor-forming composition, and a method of manufacturing the organic thin film transistor. The organic thin film transistor includes the organic semiconductor film. The organic semiconductor film includes a compound represented by a specific formula. The organic semiconductor film, the compound, and the organic thin film transistor-forming composition can be preferably used in the organic thin film transistor. The method of manufacturing the organic thin film transistor includes a step of forming an organic semiconductor film by applying the organic thin film transistor-forming composition to a substrate.

A semiconductor device includes; an active pattern on a substrate, a source/drain pattern on the active pattern, a channel pattern connected to the source/drain pattern and including semiconductor patterns spaced apart in a vertical stack, and a gate electrode extending across the channel pattern. The semiconductor patterns includes a first semiconductor pattern and a second semiconductor pattern. The gate electrode includes a first part between the substrate and the first semiconductor pattern and a second part between the first semiconductor pattern and the second semiconductor pattern. A width of the first part varies with a depth of the first part, such that a width of a middle portion of the first part is less than a width of a lower portion of the first part and a width of an upper portion of the first part.

A semiconductor device includes a first source/drain, a second source/drain isolated from direct contact with the first source/drain in a horizontal direction, a channel extending between the first source/drain and the second source/drain, a gate surrounding the channel, an upper inner spacer between the gate and the first source/drain and above the channel, and a lower inner spacer between the gate and the first source/drain and under the channel, in which the channel includes a base portion extending between the first source/drain and the second source/drain, an upper protrusion portion protruding upward from a top surface of the base portion, and a lower protrusion portion protruding downward from a bottom surface of the base portion, and a direction in which a top end of the upper protrusion portion is isolated from direct contact with a bottom end of the lower protrusion portion is oblique with respect to a vertical direction.

A method comprises forming a first fin including alternating first channel layers and first sacrificial layers and a second fin including alternating second channel layers and second sacrificial layers, forming a capping layer over the first and the second fin, forming a dummy gate stack over the capping layer, forming source/drain (S/D) features in the first and the second fin, removing the dummy gate stack to form a gate trench, removing the first sacrificial layers and the capping layer over the first fin to form first gaps, removing the capping layer over the second fin and portions of the second sacrificial layers to from second gaps, where remaining portions of the second sacrificial layers and the capping layers form a threshold voltage (V.sub.t) modulation layer, and forming a metal gate stack in the gate trench, the first gaps, and the second gaps.

A super-steep switching device is provided. The super-steep switching device may include a substrate, a semiconductor channel on the substrate, a source electrode and a drain electrode, which are disposed on the semiconductor channel and spaced apart from each other, a gate electrode overlapping a portion of the semiconductor channel and not overlapping a remaining portion of the semiconductor channel, and an insulating layer disposed between the gate electrode and the semiconductor channel and covering an entire surface of the semiconductor channel.

A semiconductor device with different configurations of nanostructured channel regions and a method of fabricating the semiconductor device are disclosed. The semiconductor device includes a fin structure disposed on a substrate, a stack of nanostructured horizontal channel (NHC) regions disposed on the fin structure, a nanostructured vertical channel (NVC) region disposed within the stack of NHC regions, a source/drain (S/D) region disposed on the fin structure, and a gate structure disposed on the NHC regions and on portions of the NVC region that are not covered by the NHC regions and the fin structure.

An aspect of the disclosure relates to an integrated circuit. The integrated circuit includes a first electrically conductive structure, a thin film crystal layer located on the first electrically conductive structure, and a second electrically conductive structure including metal e.g. copper. The second electrically conductive structure is located on the thin film crystal layer. The first electrically conductive structure is electrically connected to the second electrically conductive structure through the thin film crystal layer. The thin film crystal layer may be provided as a copper diffusion barrier.

A manufacturing method of a silicon nitride thin film, a thin film transistor, and a display panel are disclosed, the method including: providing a silane precursor into an atomic layer deposition apparatus for a preset time period, and remaining the silane precursor for a preset time period; providing an inert gas thereinto for a preset time period for the first time, and purging the silane precursor; providing a nitrogen supplying precursor for a preset time period, and remaining the nitrogen supplying precursor for a preset time period; providing the inert gas for a preset time period for the second time, and purging the nitrogen supplying precursor; repeating for a preset number of times the steps of providing the silane precursor, providing the inert gas for the first time, providing the nitrogen supplying precursor and providing the inert gas for the second time to form the silicon nitride thin film.