A semiconductor component including: a semiconductor substrate; and a semiconductor device provided thereon, the device being a field-effect transistor that includes: a gate insulating film provided on the substrate; a gate electrode provided via the film; and a pair of source-drain regions provided to sandwich the electrode, the substrate including a patterned surface in a portion where the electrode is provided, the patterned surface of the substrate including a raised portion where the film is formed to cover a surface that lies on the same plane as a surface of the pair of source-drain regions, and the electrode is formed on a top surface of the film, and the patterned surface of the substrate including a recessed portion where the film is formed to cover surfaces of a groove formed toward the interior than the surface of the pair of source-drain regions, and the electrode is formed so as to fill the groove provided with the film.

Transistors having partially recessed gates are constructed on silicon-on-insulator (SOI) semiconductor wafers provided with a buried oxide layer (BOX), for example, FD-SOI and UTBB devices. An epitaxially grown channel region relaxes constraints on the design of doped source and drain profiles. Formation of a partially recessed gate and raised epitaxial source and drain regions allow further improvements in transistor performance and reduction of short channel effects such as drain induced barrier lowering (DIBL) and control of a characteristic subthreshold slope. Gate recess can be varied to place the channel at different depths relative to the dopant profile, assisted by advanced process control. The partially recessed gate has an associated high-k gate dielectric that is initially formed in contact with three sides of the gate. Subsequent removal of the high-k sidewalls and substitution of a lower-k silicon nitride encapsulant lowers capacitance between the gate and the source and drain regions.

A method of manufacturing a semiconductor device includes providing a substrate structure, which includes a substrate, one or more semiconductor fins on the substrate, a gate structure on each fin, an active region located in said fins, and an interlayer dielectric layer covering at the active region. The method includes forming a hard mask layer over the interlayer dielectric layer and the gate structure, and using an etch process with a patterned etch mask, forming a first contact hole extending through the hard mask layer and extending into a portion of the interlayer dielectric layer, using patterned a mask. The method further includes forming a sidewall dielectric layer on sidewalls of the first contact hole, and using an etch process with the sidewall dielectric layer as an etch mask, etching the interlayer dielectric layer at bottom of the first contact hole to form a second contact hole extending to the active region.

A method includes forming a dummy gate stack, forming a dielectric layer, with the dummy gate stack located in the dielectric layer, removing the dummy gate stack to form a opening in the dielectric layer, forming a metal layer extending into the opening, and etching back the metal layer. The remaining portions of the metal layer in the opening have edges lower than a top surface of the dielectric layer. A conductive layer is selectively deposited in the opening. The conductive layer is over the metal layer, and the metal layer and the conductive layer in combination form a replacement gate.

A method for fabricating a LDMOS device in a well region of a semiconductor substrate, including: etching a polysilicon layer above the well region through a window for a body region; and forming spacers at side walls of the polysilicon layer, to define positions of source regions in the well region.

A switching device includes a semiconductor substrate; first and second trenches; gate insulating layers; and gate electrodes. The semiconductor substrate includes a first semiconductor region of a first conductivity type, a body region of a second conductivity type, a second semiconductor region of the first conductivity type, first and second bottom semiconductor regions of the second conductivity type disposed in areas extending to bottom surfaces of the first and second trenches, and a connection semiconductor region of the second conductivity type extending from the first trench to reach the second trench in a depth range from a depth of a lower end of the body region to a depth of the bottom surfaces of the first and second trenches, the connection semiconductor region contacting the second semiconductor region, and being connected to the body region, and the first and second bottom semiconductor regions.

A semiconductor device includes a substrate having source and drain regions, and a channel region arranged between the source and drain regions. The device further includes a gate structure over the substrate and adjacent to the channel region. The gate structure includes a gate stack, a spacer on sidewalls of the gate stack, and a conductor over the gate stack. The device further includes a first contact feature over the substrate and electrically connecting to at least one of the source and drain regions. A top surface of the first contact feature is lower than a top surface of the gate structure. The device further includes a first dielectric layer over the first contact feature. A top surface of the first dielectric layer is below or substantially co-planar with the top surface of the gate structure. The conductor at most partially overlaps in plan view with the first dielectric layer.

A semiconductor structure includes a source drain region of a first material and an extension region of a second material. A semiconductor device fabrication process includes forming a sacrificial dielectric portion upon a semiconductor substrate, forming a sacrificial gate stack upon the sacrificial dielectric portion, forming a gate spacer upon the sacrificial dielectric portion against the sacrificial gate, forming a source drain region of a first doped material upon the semiconductor substrate against the gate spacer, forming a replacement gate trench by removing the sacrificial gate stack, forming an extension trench by removing the sacrificial dielectric portion, and forming an extension region of a second doped material within the extension trench.

A method for forming a semiconductor structure includes forming a strained silicon germanium layer on top of a substrate. At least one patterned hard mask layer is formed on and in contact with at least a first portion of the strained silicon germanium layer. At least a first exposed portion and a second exposed portion of the strained silicon germanium layer are oxidized. The oxidizing process forms a first oxide region and a second oxide region within the first and second exposed portions, respectively, of the strained silicon germanium.

Transistors having partially recessed gates are constructed on silicon-on-insulator (SOI) semiconductor wafers provided with a buried oxide layer (BOX), for example, FD-SOI and UTBB devices. An epitaxially grown channel region relaxes constraints on the design of doped source and drain profiles. Formation of a partially recessed gate and raised epitaxial source and drain regions allow further improvements in transistor performance and reduction of short channel effects such as drain induced barrier lowering (DIBL) and control of a characteristic subthreshold slope. Gate recess can be varied to place the channel at different depths relative to the dopant profile, assisted by advanced process control. The partially recessed gate has an associated high-k gate dielectric that is initially formed in contact with three sides of the gate. Subsequent removal of the high-k sidewalls and substitution of a lower-k silicon nitride encapsulant lowers capacitance between the gate and the source and drain regions.