Disclosed is a transistor device. The transistor device includes: a semiconductor body with an active region and a pad region; at least one transistor cell including a gate electrode dielectrically insulated from a body region by a gate dielectric, wherein the body region is arranged in the active region; an electrode layer arranged above the pad region and dielectrically insulated from the pad region by a further dielectric; and a gate pad arranged above the electrode layer and electrically connected to the electrode layer and the gate electrode of the at least one transistor cell. A thickness of the further dielectric is equal to or less than a thickness of the gate dielectric.

A semiconductor device may include a pair of active patterns spaced apart from each other in a first direction, a pair of gate electrodes intersecting the pair of the active patterns in a second direction crossing the first direction, gate spacers on sidewalls of the pair of the active patterns, source/drain regions on the pair active patterns between the pair of the gate electrodes, and a spacer protection pattern between the pair of the gate electrodes and between the pair of the active patterns. The spacer protection pattern may be commonly connected to the gate spacers.

Provided is a three-dimensional semiconductor device and its fabrication method. The semiconductor device includes a first active region on a substrate and including a plurality of lower channel patterns and a plurality of lower source/drain patterns that are alternately arranged along a first direction, a second active region on the first active region and including a plurality of upper channel patterns and a plurality of upper source/drain patterns that are alternately arranged along the first direction, a first gate electrode on a first lower channel pattern of the lower channel patterns and on a first upper channel pattern of the upper channel patterns, and a second gate electrode on a second lower channel pattern of the lower channel patterns and on a second upper channel pattern of the upper channel patterns. The second gate electrode may include lower and upper gate electrodes with an isolation pattern interposed therebetween.

A semiconductor device includes a fin structure, a first conductive line, a second conductive line and a first conductive rail. The fin structure is disposed on a substrate. The first conductive line is arranged to wrap a first portion of the fin structure. The second conductive line is attached on a second portion of the fin structure. The second portion is different from the first portion. The first conductive rail is disposed in a same layer as the first conductive line and the second conductive line on the substrate. The first conductive rail is attached on one end of the first conductive line and one end of the second conductive line for electrically connecting the first conductive line and the second conductive line.

A FinFET structure with a gate structure having two notch features therein and a method of forming the same is disclosed. The FinFET notch features ensure that sufficient spacing is provided between the gate structure and source/drain regions of the FinFET to avoid inadvertent shorting of the gate structure to the source/drain regions. Gate structures of different sizes (e.g., different gate widths) and of different pattern densities can be provided on a same substrate and avoid inadvertent of shorting the gate to the source/drain regions through application of the notched features.

A transistor includes a plurality of gate fingers that extend in a first direction and are spaced apart from each other in a second direction, each of the gate fingers comprising at least spaced-apart and generally collinear first and second gate finger segments that are electrically connected to each other. The first gate finger segments are separated from the second gate finger segments in the first direction by a gap region that extends in the second direction. A resistor is disposed in the gap region.

A method for producing a semiconductor device includes forming a first insulating film around a fin-shaped semiconductor layer and forming a pillar-shaped semiconductor layer and forming a second diffusion layer in an upper portion of the fin-shaped semiconductor layer and a lower portion of the pillar-shaped semiconductor layer. A metal-semiconductor compound is formed on the second diffusion layer. A first metal is deposited to form a gate electrode and a gate line. Second and third metal films are deposited to form a first contact in which the second metal film surrounds a sidewall of an upper portion of the pillar-shaped semiconductor layer, and a second contact connects an upper portion of the first contact and an upper portion of the pillar-shaped semiconductor layer. A third contact is formed on the gate line.

A semiconductor device includes a pillar-shaped semiconductor layer and a first gate insulating film around the pillar-shaped semiconductor layer. A metal gate electrode is around the first gate insulating film and a metal gate line is connected to the gate electrode. A second gate insulating film is around a sidewall of an upper portion of the pillar-shaped semiconductor layer and a first contact made of a second metal surrounds the second gate insulating film. An upper portion of the first contact is electrically connected to an upper portion of the pillar-shaped semiconductor layer, and a third contact resides on the metal gate line. A lower portion of the third contact is made of the second metal.

A work function setting metal stack includes a configuration of layers including a high dielectric constant layer and a diffusion prevention layer formed on the high dielectric constant layer. An aluminum doped TiC layer has a thickness greater than 5 nm wherein the configuration of layers is employed between two regions as a diffusion barrier to prevent mass diffusion between the two regions.

A work function setting metal stack includes a configuration of layers including a high dielectric constant layer and a diffusion prevention layer formed on the high dielectric constant layer. An aluminum doped TiC layer has a thickness greater than 5 nm wherein the configuration of layers is employed between two regions as a diffusion barrier to prevent mass diffusion between the two regions.