A semiconductor device includes a first channel region disposed over a substrate, and a first gate structure disposed over the first channel region. The first gate structure includes a gate dielectric layer disposed over the channel region, a lower conductive gate layer disposed over the gate dielectric layer, a ferroelectric material layer disposed over the lower conductive gate layer, and an upper conductive gate layer disposed over the ferroelectric material layer. The ferroelectric material layer is in direct contact with the gate dielectric layer and the lower gate conductive layer, and has a U-shape cross section.

A semiconductor device may include a substrate including first and second active regions and a field region therebetween, first and second active patterns respectively provided on the first and second active regions, first and second source/drain patterns respectively provided on the first and second active patterns, a first channel pattern between the first source/drain patterns and a second channel pattern between the second source/drain patterns, and a gate electrode extended from the first channel pattern to the second channel pattern to cross the field region. Each of the first and second channel patterns may include semiconductor patterns, which are stacked to be spaced apart from each other. A width of a lower portion of the gate electrode on the field region may decrease with decreasing distance from a top surface of the substrate.

A semiconductor device includes a first metal-oxide-semiconductor (MOS) transistor and a second MOS transistor on a substrate. The second MOS transistor is electrically connected to the first MOS transistor. The first MOS transistor includes a first gate dielectric layer and a first gate electrode on the first gate dielectric layer. The second MOS transistor includes a second gate dielectric layer and a second gate electrode on the second gate dielectric layer. The second gate electrode includes a first portion of a first conductivity type and second portions of a second conductivity type on opposite sides of the first portion. The width of the first portion is less than half of the total width of the second gate electrode.

The present invention provides a method for forming a layout pattern of static random access memory, comprising forming a PU1 (first pull-up transistor), a PU2 (second pull-up transistor), a PD1A (first pull-down transistor), a PD1B (second pull-down transistor), a PD2A (third pull-down transistor), a PD2B (fourth pull-down transistor), a PG1A (first access transistor), a PG1B (second access transistor), a PG2A (third access transistor) and a PG2B (fourth access transistor) located on the substrate. The PD1A and the PD1B are connected in parallel with each other, the PD2A and the PD2B are connected in parallel with each other, wherein the gate structures include a first J-shaped gate structure, and the first J-shaped gate structure is an integrally formed structure.

An HEMT device, comprising: a semiconductor body including a heterojunction structure; a dielectric layer on the semiconductor body; a gate electrode; a drain electrode, facing a first side of the gate electrode; and a source electrode, facing a second side opposite to the first side of the gate electrode; an auxiliary channel layer, which extends over the heterojunction structure between the gate electrode and the drain electrode, in electrical contact with the drain electrode and at a distance from the gate electrode, and forming an additional conductive path for charge carriers that flow between the source electrode and the drain electrode.

A MOS transistor including a substrate, a conductive having lateral walls, drain and source regions, and spacers having an upper surface such that the spacers are buried in the substrate and are position between the conductive gate and the drain and source regions is provided. The spacers are each cuboid-shaped and have a width that is constant along the spacers height and independent from a height of the conductive gate. A device including the MOS transistor and a method of manufacture for producing a right-hand portion and a left-hand portion of a MOS transistor is also provided.

A field-effect transistor (a GaN-based HFET) includes a gate electrode, a gate electrode pad, a first wiring line connecting one end of the gate electrode and the gate electrode pad, a second wiring line connecting the other end of the gate electrode and the gate electrode pad, and a resistance element that is connected to the first wiring line and is capable of adjusting the impedance of the first wiring line.

A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define vertical drift regions of the transistor, so that each vertical drift region is bounded on at least two opposite sides by the deep trench structures. The deep trench structures are spaced so as to form RESURF regions for the drift region. Trench gates are formed in trenches in the substrate over the vertical drift regions. The body regions are located in the substrate over the vertical drift regions.

A semiconductor device includes a gate structure having a gate conductor and a sidewall spacer. A partial dielectric cap is formed on the gate conductor and extends less than a width of the gate conductor. A self-aligned contact is formed adjacent to the sidewall spacer of the gate structure and is electrically isolated from the gate conductor by the partial dielectric cap and the sidewall spacer.

The semiconductor device includes: a channel layer, a barrier layer, a first insulating film, and a second insulating film, each of which is formed above a substrate; a trench that penetrates the second insulating film, the first insulating film, and the barrier layer to reach the middle of the channel layer; and a gate electrode arranged in the trench and over the second insulating film via a gate insulating film. The bandgap of the second insulating film is smaller than that of the first insulating film, and the bandgap of the second insulating film is smaller than that of the gate insulating film GI. Accordingly, a charge (electron) can be accumulated in the second (upper) insulating film, thereby allowing the electric field strength at a corner of the trench to be improved. As a result, a channel is fully formed even at a corner of the trench, thereby allowing an ON-resistance to be reduced and an ON-current to be increased.