A semiconductor device is provided that includes a first plurality of fin structures having a first width in a first region of a substrate, and a second plurality of fin structures having a second width in a second region of the substrate, the second width being less than the first width. A first gate structure is formed on the first plurality of fin structures including a first high-k gate dielectric that is in direct contact with a channel region of the first plurality of fin structures and a first gate conductor. A second gate structure is formed on the second plurality of fin structures including a high voltage gate dielectric that is in direct contact with a channel region of the second plurality of fin structures, a second high-k gate dielectric and a second gate conductor.

An integrated circuit device may include a gate insulation layer covering a top surface and opposite sidewalls of a fin-shaped active region, a gate electrode covering the gate insulation layer and a hydrogen atomic layer disposed along an interface between the fin-shaped active region and the gate insulation layer. A method of manufacturing the integrated circuit device may include forming an insulating layer covering a lower portion of a preliminary fin-shaped active region, forming a fin-shaped active region having an outer surface with an increased smoothness through annealing an upper portion of the preliminary fin-shaped active region in a hydrogen atmosphere and forming a hydrogen atomic layer covering the outer surface of the fin-shaped active region. A gate insulation layer and a gate electrode may be formed to cover a top surface and opposite sidewalls of the fin-shaped active region.

A device, structure, and method are provided whereby an insert layer is utilized to provide additional support for surrounding dielectric layers. The insert layer may be applied between two dielectric layers. Once formed, trenches and vias are formed within the composite layers, and the insert layer will help to provide support that will limit or eliminate undesired bending or other structural motions that could hamper subsequent process steps, such as filling the trenches and vias with conductive material.

The present disclosure provides a method for forming patterns in a semiconductor device. The method includes providing a substrate and a patterning-target layer over the substrate; patterning the patterning-target layer to form a main pattern; forming a middle layer over the patterning-target layer and a hard mask layer over the middle layer; patterning the hard mask layer to form a first cut pattern; patterning the hard mask layer to form a second cut pattern, a combined cut pattern being formed in the hard mask layer as a union of the first cut pattern and the second cut pattern; transferring the combined cut pattern to the middle layer; etching the patterning-target layer using the middle layer as an etching mask to form a final pattern in the patterning-target layer. In some embodiments, the final pattern includes the main pattern subtracting an intersection portion between main pattern and the combined cut pattern.

A method for forming the semiconductor device that includes forming a plurality of composite fin structures across a semiconductor substrate including an active device region and an isolation region. The composite fin structures may include a semiconductor portion over the active device region and a dielectric portion over the isolation region. A gate structure can be formed on the channel region of the fin structures that are present on the active regions of the substrate, and the gate structure is also formed on the dielectric fin structures on the isolation regions of the substrate. Epitaxial source and drain regions are formed on source and drain portions of the fin structures present on the active region, wherein the dielectric fin structures support the gate structure over the isolation regions.

A method of forming a vertical fin field effect transistor (vertical finFET) with an increased surface area between a source/drain contact and a doped region, including forming a doped region on a substrate, forming one or more interfacial features on the doped region, and forming a source/drain contact on at least a portion of the doped region, wherein the one or more interfacial features increases the surface area of the interface between the source/drain contact and the doped region compared to a flat source/drain contact-doped region interface.

The present invention relates generally to semiconductors, and more particularly, to a structure and method of minimizing shorting between epitaxial regions in small pitch fin field effect transistors (FinFETs). In an embodiment, a dielectric region may be formed in a middle portion of a gate structure. The gate structure be formed using a gate replacement process, and may cover a middle portion of a first fin group, a middle portion of a second fin group and an intermediate region of the substrate between the first fin group and the second fin group. The dielectric region may be surrounded by the gate structure in the intermediate region. The gate structure and the dielectric region may physically separate epitaxial regions formed on the first fin group and the second fin group from one another.

A nonplanar semiconductor device having a semiconductor body formed on an insulating layer of a substrate. The semiconductor body has a top surface opposite a bottom surface formed on the insulating layer and a pair of laterally opposite sidewalls wherein the distance between the laterally opposite sidewalls at the top surface is greater than at the bottom surface. A gate dielectric layer is formed on the top surface of the semiconductor body and on the sidewalls of the semiconductor body. A gate electrode is formed on the gate dielectric layer on the top surface and sidewalls of the semiconductor body. A pair of source/drain regions are formed in the semiconductor body on opposite sides of the gate electrode.

A semiconductor device includes a fin region with long and short sides, a first field insulating layer including a top surface lower than that of the fin region and adjacent to a side surface of the short side of the fin region, a second field insulating layer including a top surface lower than that of the fin region and adjacent to a side surface of the long side of the fin region, an etch barrier pattern on the first field insulating layer, a first gate on the fin region and the second field insulating layer to face a top surface of the fin region and side surfaces of the long sides of the fin region. A second gate is on the etch barrier pattern overlapping the first field insulating layer. A source/drain region is between the first gate and the second gate, in contact with the etch barrier pattern.

A method of forming a semiconductor device that includes providing a first set of fin structures having a first pitch, and a second set of fin structure having a second pitch, wherein the second pitch is greater than the first pitch. An epitaxial semiconductor material on the first and second set of fin structures. The epitaxial semiconductor material on the first fin structures is merging epitaxial material and the epitaxial material on the second fin structures is non-merging epitaxial material. A dielectric liner is formed atop the epitaxial semiconductor material that is present on the first and second sets of fin structures. The dielectric liner is removed from a portion of the non-merging epitaxial material that is present on the second set of fin structures. A bridging epitaxial semiconductor material is formed on exposed surfaces of the non-merging epitaxial material.