A gate electrode (3) is provided on a main surface of a silicon substrate (1) via a gate insulating film (2). A source/drain region (4,5) is provided on sides of the gate electrode (3) on the main surface of the silicon substrate (1). A first silicide (6) is provided on an upper face and side faces of the gate electrode (3). A second silicide (7) is provided on a surface of the source/drain region (4,5). No side-wall oxide film is provided on the side faces of the gate electrode (3). The second silicide (7) is provided at a point separated from the gate electrode (3).

Disclosed examples include LDMOS transistors and integrated circuits with a gate, a body region implanted in the substrate to provide a channel region under a portion of the gate, a source adjacent the channel region, a drain laterally spaced from a first side of the gate, a drift region including a first highly doped drift region portion, a low doped gap drift region above the first highly doped drift region portion, and a second highly doped region portion above the gap drift region, and an isolation structure extending through the second highly doped region portion into the gap drift region portion, with a first end proximate the drain region and a second end under the gate dielectric layer, where the body region includes a tapered side laterally spaced from the second end of the isolation structure to define a trapezoidal JFET region.

The present disclosure, in some embodiments, relates to a transistor device within an active area having a shape configured to reduce a susceptibility of the transistor device to performance degradation (e.g., the kink effect) caused by divots in an adjacent isolation structure. The transistor device has a substrate including interior surfaces defining a trench within an upper surface of the substrate. One or more dielectric materials are arranged within the trench. The one or more dielectric materials define an opening exposing the upper surface of the substrate. The opening has a source opening over a source region within the substrate, a drain opening over a drain region within the substrate, and a channel opening between the source opening and the drain opening. The source opening and the drain opening have widths smaller than the channel opening. A gate structure extends over the opening between the source and drain regions.

The present disclosure, in some embodiments, relates to a method of forming an integrated chip. The method includes forming an isolation structure within an upper surface of a substrate. The isolation structure surrounds a continuous region of the substrate defining a source area, a drain area, and a channel area. A gate structure is formed over the channel area. An implantation process is performed to form a source region within the source area and a drain region within the drain area. The channel area is arranged between the source region and the drain region along a first direction and extends past the source region and the drain region along a second direction that is perpendicular to the first direction. The first direction and the second direction are parallel to the upper surface of the substrate.

In method of manufacturing a semiconductor device, a source/drain epitaxial layer is formed, one or more dielectric layers are formed over the source/drain epitaxial layer, an opening is formed in the one or more dielectric layers to expose the source/drain epitaxial layer, a first silicide layer is formed on the exposed source/drain epitaxial layer, a second silicide layer different from the first silicide layer is formed on the first silicide layer, and a source/drain contact is formed over the second silicide layer.

Various methods and structures for fabricating a contact for a semiconductor FET or FinFET device. A semiconductor FET structure includes a substrate, a source/drain region layer and source/drain contact. First and second gate spacers are adjacent respective first and second opposing sides of the source/drain contact. The source/drain contact is disposed directly on and contacting the entire source/drain region layer, and at a vertical level thereabove, the source/drain contact being recessed to a limited horizontal area continuing vertically upwards from the vertical level. The limited horizontal area horizontally extending along less than a full horizontal length of a vertical sidewall of the first and second gate spacers, and less than fully covering the source/drain region layer. A method uses a reverse contact mask to form a shape of the source/drain contact into an inverted T shape.

A field effect transistor for a high voltage operation can include vertical current paths, which may include vertical surface regions of a pedestal semiconductor portion that protrudes above a base semiconductor portion. The pedestal semiconductor portion can be formed by etching a semiconductor material layer employing a gate structure as an etch mask. A dielectric gate spacer can be formed on sidewalls of the pedestal semiconductor portion. A source region and a drain region may be formed underneath top surfaces of the base semiconductor portion. Alternatively, epitaxial semiconductor material portions can be grown on the top surfaces of the base semiconductor portions, and a source region and a drain region can be formed therein. Alternatively, a source region and a drain region can be formed within via cavities in a planarization dielectric layer.

A semiconductor device includes a first nanosheet stack, a second nanosheet stack, and a third nanosheet stack arranged on a substrate. The semiconductor device includes a gate arranged on the first nanosheet stack, the second nanosheet stack, and the third nanosheet stack. The semiconductor device includes a channel extending through the gate and from the first nanosheet stack, the second nanosheet stack, and to the third nanosheet stack in a serpentine fashion. The semiconductor device includes a first source/drain and a second source/drain arranged on opposing sides of the gate.

A semiconductor structure including a first substantially U-shaped and/or H-shaped channel is disclosed. The semiconductor structure may further include a second substantially U-shaped and/or H-shaped channel positioned above the first channel. A method of forming a substantially U-shaped and/or H-shaped channel is also disclosed. The method may include forming a fin structure on a substrate where the fin structure includes an alternating layers of sacrificial semiconductor and at least one silicon layer or region. The method may further include forming additional silicon regions vertically on sidewalls of the fin structure. The additional silicon regions may contact the silicon layer or region of the fin structure to form the substantially U-shaped and/or H-shaped channel(s). The method may further include removing the sacrificial semiconductor layers and forming a gate structure around the substantially U-shaped and/or substantially H-shaped channels.

The demand for increased performance and shrinking geometry from ICs has brought the introduction of multi-gate devices including finFET devices. Inducing a higher tensile strain/stress in a region provides for enhanced electron mobility, which may improve performance. High temperature processes during device fabrication tend to relax the stress on these strain inducing layers. In some embodiments, the present disclosure relates to a finFET device and its formation. A strain-inducing layer is disposed on a semiconductor fin between a channel region and a metal gate electrode. First and second inner spacers are disposed on a top surface of the strain-inducing layer and have inner sidewalls disposed along outer sidewalls of the metal gate electrode. First and second outer spacers have innermost sidewalls disposed along outer sidewalls of the first and second inner spacers, respectively. The first and second outer spacers cover outer sidewalls of the first and second inner spacers.