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.

An electrical device that in some embodiments includes a substrate including a lateral device region and a vertical device region. A lateral diffusion metal oxide semiconductor (LDMOS) device may be present in the lateral device region, wherein a drift region of the LDMOS device has a length that is parallel to an upper surface of the substrate in which the LDMOS device is formed. A vertical field effect transistor (VFET) device may be present in the vertical device region, wherein a vertical channel of the VFET has a length that is perpendicular to said upper surface of the substrate, the VFET including a gate structure that is positioned around the vertical channel.

A metal oxide semiconductor field effect transistors (MOSFET) memory array, including a complementary metal oxide semiconductor (CMOS) cell including an n-type MOSFET having a modified gate dielectric; and an n-type or p-type MOSFET having an unmodified gate dielectric layer, where the modified gate dielectric layer incorporates an oxygen scavenging species.

An asymmetric high-k dielectric for reduced gate induced drain leakage in high-k MOSFETs and methods of manufacture are disclosed. The method includes performing an implant process on a high-k dielectric sidewall of a gate structure. The method further includes performing an oxygen annealing process to grow an oxide region on a drain side of the gate structure, while inhibiting oxide growth on a source side of the gate structure adjacent to a source region.

A manufacturing method of a trench power MOSFET is provided. In the manufacturing method, the trench gate structure of the trench power MOSFET is formed in the epitaxial layer and includes an upper doped region, a lower doped region and a middle region interposed therebetween. The upper doped region has a conductive type reverse to that of the lower doped region, and the middle region is an intrinsic or lightly-doped region to form a PIN, P.sup.+/N.sup. or N.sup.+/P.sup. junction. As such, when the trench power MOSFET is in operation, a junction capacitance formed at the PIN, P.sup.+/N.sup. or N.sup.+/P.sup. junction is in series with the parasitic capacitance. Accordingly, the gate-to-drain effective capacitance may be reduced.

Deterioration in reliability is prevented regarding a semiconductor device. The deterioration is caused when an insulating film for formation of a sidewall is embedded between gate electrodes at the time of forming sidewalls having two kinds of different widths on a substrate. A sidewall-shaped silicon oxide film is formed over each sidewall of a gate electrode of a low breakdown voltage MISFET and a pattern including a control gate electrode and a memory gate electrode. Then, a silicon oxide film beside the gate electrode is removed, and a silicon oxide film is formed on a semiconductor substrate, and then etchback is performed. Accordingly, a sidewall, formed of a silicon nitride film and the silicon oxide film, is formed beside the gate electrode, and a sidewall, formed of the silicon nitride film and the silicon oxide films, is formed beside the pattern.

A semiconductor device is provided, including: a substrate having a first area and a second area; several first gate structures formed at the first area, and at least one of the first gate structures including a first hardmask on a first gate, and the first gate structure having a first gate length; several second gate structures formed at the second area, and at least one of the second gate structures including a second hardmask on a second gate, and the second gate structure having a second gate length. The first gate length is smaller than the second gate length, and the first hardmask contains at least a portion of nitrogen (N.sub.2)-based silicon nitride (SiN) which is free of OH concentration.

Provided is a semiconductor device having improved performance. Over a semiconductor substrate, a dummy control gate electrode is formed via a first insulating film. Over the semiconductor substrate, a memory gate electrode for a memory cell is formed via a second insulating film having an internal charge storage portion so as to be adjacent to the dummy control gate electrode. At this time, the height of the memory gate electrode is adjusted to be lower than the height of the dummy control gate electrode. Then, a third insulating film is formed so as to cover the dummy control gate electrode and the memory gate electrode. Then, the third insulating film is polished to expose the dummy control gate electrode. At this time, the memory gate electrode is not exposed. Then, the dummy control gate electrode is removed and replaced with a metal gate electrode.

A method of fabricating advanced node field effect transistors using a replacement metal gate process. The method includes dopant a high-k dielectric directly or indirectly by using layers composed of multi-layer thin film stacks, or in other embodiments, by a single blocking layer. By taking advantage of unexpected etch selectivity of the multi-layer stack or the controlled etch process of a single layer stack, etch damage to the high-k may be avoided and work function metal thicknesses can be tightly controlled which in turn allows field effect transistors with low Tinv (inverse of gate capacitance) mismatch.

A method for forming semiconductor devices includes forming a highly doped region. A stack of alternating layers is formed on the substrate. The stack is patterned to form nanosheet structures. A dummy gate structure is formed over and between the nanosheet structures. An interlevel dielectric layer is formed. The dummy gate structures are removed. SG regions are blocked, and top sheets are removed from the nanosheet structures along the dummy gate trench. A bottommost sheet is released and forms a channel for a field effect transistor device by etching away the highly doped region under the nanosheet structure and layers in contact with the bottommost sheet. A gate structure is formed in and over the dummy gate trench wherein the bottommost sheet forms a device channel for the EG device.