In some embodiments, the present disclosure relates to a semiconductor device that includes a well region with a substrate. A source region and a drain region are arranged within the substrate on opposite sides of the well region. A gate electrode is arranged over the well region, has a bottom surface arranged below a topmost surface of the substrate, and extends between the source and drain regions. A trench isolation structure surrounds the source region, the drain region, and the gate electrode. A gate dielectric structure separates the gate electrode from the well region, the source, region, the drain region, and the trench isolation structure. The gate electrode structure has a central portion and a corner portion. The central portion has a first thickness, and the corner portion has a second thickness that is greater than the first thickness.

Various embodiments of the present disclosure provide a method for forming a recessed gate electrode that has high thickness uniformity. A gate dielectric layer is deposited lining a recess, and a multilayer film is deposited lining the recess over the gate dielectric layer. The multilayer film comprises a gate electrode layer, a first sacrificial layer over the gate dielectric layer, and a second sacrificial layer over the first sacrificial dielectric layer. A planarization is performed into the second sacrificial layer and stops on the first sacrificial layer. A first etch is performed into the first and second sacrificial layers to remove the first sacrificial layer at sides of the recess. A second etch is performed into the gate electrode layer using the first sacrificial layer as a mask to form the recessed gate electrode. A third etch is performed to remove the first sacrificial layer after the second etch.

A high voltage device includes drift regions formed in a substrate, an isolation layer formed in the substrate to isolate neighboring drift regions, wherein the isolation layer has a depth greater than that of the drift region, a gate electrode formed over the substrate, and source and drain regions formed in the drift regions on both sides of the gate electrode.

Present disclosure provides a FinFET structure, including a plurality of fins, a gate, and a first dopant layer. The gate is disposed substantially orthogonal over the plurality of fins, covering a portion of a top surface and a portion of sidewalls of the plurality of fins. The first dopant layer covers the top surface and the sidewalls of a junction portion of a first fin, configured to provide dopants of a first conductive type to the junction portion of the first fin. The junction portion is adjacent to the gate.

A field effect transistor having a higher breakdown voltage can be provided by forming a contiguous dielectric material layer over gate stacks, forming via cavities laterally spaced from the gate stacks, selectively depositing a single crystalline semiconductor material, and converting upper portions of the deposited single crystalline semiconductor material into elevated source/drain regions. Lower portions of the selectively deposited single crystalline semiconductor material in the via cavities can have a doping of a lesser concentration, thereby effectively increasing the distance between two steep junctions at edges of a source region and a drain region. Optionally, embedded active regions for additional devices can be formed prior to formation of the contiguous dielectric material layer. Raised active regions contacting a top surface of a substrate can be formed simultaneously with formation of the elevated active regions that are vertically spaced from the top surface.

A method of processing a semiconductor device is presented. The method includes providing a semiconductor body; forming a trench within the semiconductor body, the trench having a stripe configuration and extending laterally within an active region of the semiconductor body that is surrounded by a non-active region of the semiconductor body; forming, within the trench, a first electrode and a first insulator insulating the first electrode from the semiconductor body; carrying out a first etching step for partially removing the first electrode along the total lateral extension of the first electrode such that the remaining part of the first electrode has a planar surface, thereby creating a well in the trench that is laterally confined by the first insulator; depositing a second insulator on top the planar surface; and forming a second electrode within the well of the trench. The second insulator insulates the second electrode from the first electrode.

An integrated circuit structure includes a gate stack over a semiconductor substrate, and an opening extending into the semiconductor substrate, wherein the opening is adjacent to the gate stack. A first silicon germanium region is disposed in the opening, wherein the first silicon germanium region has a first germanium percentage. A second silicon germanium region is over the first silicon germanium region. The second silicon germanium region comprises a portion in the opening. The second silicon germanium region has a second germanium percentage greater than the first germanium percentage. A silicon cap substantially free from germanium is over the second silicon germanium region.

A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate having a logic region and high-voltage (HV) region; forming a first gate structure on the logic region and a second gate structure on the HV region; forming an interlayer dielectric (ILD) layer around the first gate structure and the second gate structure; forming a patterned hard mask on the HV region; and transforming the first gate structure into a metal gate.

A semiconductor device includes a transistor configuration including first and second gate electrodes, each of the first and second gate electrodes having at least a bottom layer and an upper layer including polycrystalline silicon grains, wherein the first gate electrode is a nMOS gate electrode formed in an nMOS region of the transistor configuration, wherein the polycrystalline silicon grains included in the bottom layer of the first gate electrode have a greater particle diameter than the polycrystalline grains included in the upper layer of the second gate electrode.

A semiconductor device is disclosed. The semiconductor device includes: a substrate, a gate structure on the substrate, a spacer adjacent to the gate structure, an epitaxial layer in the substrate adjacent to two sides of the spacer, and a dislocation embedded within the epitaxial layer. Preferably, the top surface of the epitaxial layer is lower than the top surface of the substrate, and the top surface of the epitaxial layer has a V-shape.