High voltage devices and methods for forming a high voltage device are disclosed. The method includes providing a substrate having top and bottom surfaces. The substrate is defined with a device region and a recessed region disposed within the device region. The recessed region includes a recessed surface disposed lower than the top surface of the substrate. A transistor is formed over the substrate. Forming the transistor includes forming a gate at least over the recessed surface and forming a source region adjacent to a first side of the gate below the recessed surface. Forming the transistor also includes forming a drain region displaced away from a second side of the gate. First and second device wells are formed in the substrate within the device region. The first device well encompasses the drain region and the second device well encompasses the source region.

A nanowire transistor is provided that includes a well implant having a local isolation region for insulating a replacement metal gate from a parasitic channel. In addition, the nanowire transistor includes oxidized caps in the extension regions that inhibit parasitic gate-to-source and gate-to-drain capacitances.

The present disclosure provides a bio-field effect transistor (BioFET) and a method of fabricating a BioFET device. The method includes forming a BioFET using one or more process steps compatible with or typical to a complementary metal-oxide-semiconductor (CMOS) process. The BioFET device may include a substrate; a gate structure disposed on a first surface of the substrate and an interface layer formed on the second surface of the substrate. The interface layer may allow for a receptor to be placed on the interface layer to detect the presence of a biomolecule or bio-entity. An amplification factor of the BioFET device may be provided by a difference in capacitances associated with the gate structure on the first surface and with the interface layer formed on the second surface.

A semiconductor device includes a substrate extending in a first direction to define a substrate length and a second direction perpendicular to the first direction to define a substrate width. A first semiconductor fin is formed on an upper surface of the substrate. The first semiconductor fin extends along the second direction at a first distance to define a first fin width. A second semiconductor fin is formed on the upper surface of the substrate. The second semiconductor fin extends along the second direction at a second distance to define a second fin width. The second distance may be different with respect to the first distance such that the first and second fin widths are different with respect to one another.

A method of making a semiconductor device in a gate first process with side gate assists. A first gate may be formed within a gate region. The first gate may include a first gate conductor separated from a semiconductor substrate by a first insulator disposed between the first gate conductor and the semiconductor substrate. A second gate may be formed within the gate region. The second gate may include a second gate conductor separated from a vertical surface of the first gate conductor and the semiconductor substrate by a second insulator. A first electrical contact and a second electrical contact may be formed. The first and second electrical contacts may be disposed on opposite ends of the gate region for respectively connecting the first gate conductor and the second gate conductor to a respective voltage.

A multi-gate transistor includes a semiconductor fin over a substrate. The semiconductor fin includes a central fin formed of a first semiconductor material; and a semiconductor layer having a first portion and a second portion on opposite sidewalls of the central fin. The semiconductor layer includes a second semiconductor material different from the first semiconductor material. The multi-gate transistor further includes a gate electrode wrapping around sidewalls of the semiconductor fin; and a source region and a drain region on opposite ends of the semiconductor fin. Each of the central fin and the semiconductor layer extends from the source region to the drain region.

A method of forming a semiconductor device structure is disclosed including providing a first active region and a second active region in an upper surface portion of a substrate, the first and second active regions being laterally separated by at least one isolation structure, forming a first gate structure comprising a first gate dielectric and a first gate electrode material over the first active region, and a second gate structure comprising a second gate dielectric and a second gate electrode material over the second active region, wherein a thickness of the second gate dielectric is greater than the thickness of the first gate dielectric, and forming a first sidewall spacer structure to the first gate structure and a second sidewall spacer structure to the second gate structure, wherein a lateral thickness of the second sidewall spacer structure is greater than a lateral thickness of the first sidewall spacer structure.

A device includes a source region, a drain region, and a wurtzite semiconductor between the source region and the drain region. A source-drain direction is parallel to a [01-10] direction or a [2110] direction of the wurtzite semiconductor. The device further includes a gate dielectric over the wurtzite semiconductor, and a gate electrode over the gate dielectric.

A device includes a semiconductor layer of a first conductivity type, and a first and a second body region over the semiconductor layer, wherein the first and the second body regions are of a second conductivity type opposite the first conductivity type. A doped semiconductor region of the first conductivity type is disposed between and contacting the first and the second body regions. A gate dielectric layer is disposed over the first and the second body regions and the doped semiconductor region. A first and a second gate electrode are disposed over the gate dielectric layer, and overlapping the first and the second body regions, respectively. The first and the second gate electrodes are physically separated from each other by a space, and are electrically interconnected. The space between the first and the second gate electrodes overlaps the doped semiconductor region.

The present invention relates to the field of manufacturing technologies of semiconductor power devices, and more particularly to a method for manufacturing a split-gate power device. In the method for manufacturing a split-gate power device according to the present invention, lateral etching is added to form lateral recesses of a control gate groove below a first insulating film in a process of forming the control gate groove by etching, and therefore, after a first conductive film is deposited, the first conductive film can be directly etched by using the first insulating film as a mask to form control gates. The technical process of the present invention is simplified, reliable and easy to control, and can greatly improve the yield of the split-gate power device. The present invention is particularly suitable for the manufacture of 25V-200V semiconductor power devices.