A method comprises providing a substrate with a second conductivity type, growing a first epitaxial layer having the second conductivity type, growing a second epitaxial layer having a first conductivity type, forming a trench in the first epitaxial layer and the second epitaxial layer, forming a gate electrode in the trench, applying an ion implantation process using first gate electrode as an ion implantation mask to form a drain-drift region, forming a field plate in the trench, forming a drain region in the second epitaxial layer, wherein the drain region has the first conductivity type and forming a source region in the first epitaxial layer, wherein the source region has the first conductivity type, and wherein the source region is electrically coupled to the field plate.

A method for fabricating a semiconductor structure is provided that includes the steps of: forming a structure including a substrate, a counter-doped layer on the substrate, and a heavily doped source contact layer on a side of the counter-doped layer opposite the substrate; and forming an oxide layer on a side of the heavily doped source contact layer opposite the counter-doped layer, wherein the oxide layer has a vertical dimension that is a difference between a length of a long channel thick oxide device and a length of a short channel non-thick oxide device.

An electronic circuit includes a plurality of fin lines on a substrate and a plurality of gate lines with a first line width, crossing over the fin lines. The gate lines are parallel and have a plurality of discontinuous regions forming as a plurality of slots. A region of any one of the gate lines adjacent to an unbalance of the slots has a second line width smaller than the first line width.

A semiconductor device including a substrate includes a first region and a second region and first and second transistors in the first and second regions, respectively. The first transistor includes a first gate insulating layer on the substrate, a first lower TiN layer on and in contact with the first gate insulating layer, a first etch-stop layer on the first lower TiN layer and a first upper gate electrode on the first etch-stop layer. The second transistor includes a second gate insulating layer on the substrate, a second lower TiN layer on and in contact with the second gate insulating layer, a second etch-stop layer on the second lower TiN layer and a second upper gate electrode on the second etch-stop layer. A thickness of the first lower TiN layer is less than a thickness of the second lower TiN layer

A semiconductor device includes a substrate including a fin-shaped active region that protrudes from the substrate; a gate insulating film covering a top surface and both side walls of the fin-shaped active region; a gate electrode on the top surface and the both side walls of the fin-shaped active region and covering the gate insulating film; one pair of insulating spacers on both side walls of the gate electrode; and a source region and a drain region on the substrate and respectively located on sides of the gate electrode. The source region and the drain region form a source/drain pair. The one pair of insulating spacers include protrusions that protrude from upper portions of the one pair of insulating spacers toward the gate electrode.

Some embodiments of the present disclosure provide a semiconductor device. The semiconductor device includes a semiconductive substrate. A donor-supply layer is over the semiconductive substrate. The donor-supply layer includes a top surface. A gate structure, a drain, and a source are over the donor-supply layer. A passivation layer covers conformally over the gate structure and the donor-supply layer. A gate electrode is over the gate structure. A field plate is disposed on the passivation layer between the gate electrode and the drain. The field plate includes a bottom edge. The gate electrode having a first edge in proximity to the field plate, the field plate comprising a second edge facing the first edge, a horizontal distance between the first edge and the second edge is in a range of from about 0.05 to about 0.5 micrometers.

A semiconductor device includes plurality of fin structures extending in first direction on semiconductor substrate. Fin structure's lower portion is embedded in first insulating layer. First gate electrode and second gate electrode structures extend in second direction substantially perpendicular to first direction over of fin structures and first insulating layer. The first and second gate electrode structures are spaced apart and extend along line in same direction. First and second insulating sidewall spacers are arranged on opposing sides of first and second gate electrode structures. Each of first and second insulating sidewall spacers contiguously extend along second direction. A second insulating layer is in region between first and second gate electrode structures. The second insulating layer separates first and second gate electrode structures. A third insulating layer is in region between first and second gate electrode structures. The third insulating layer is formed of different material than second insulating layer.

Semiconductor device(s) including a transistor with a gate electrode having a work function monotonically graduating across the gate electrode length, and method(s) to fabricate such a device. In embodiments, a gate metal work function is graduated between source and drain edges of the gate electrode for improved high voltage performance. In embodiments, thickness of a gate metal graduates from a non-zero value at the source edge to a greater thickness at the drain edge. In further embodiments, a high voltage transistor with graduated gate metal thickness is integrated with another transistor employing a gate electrode metal of nominal thickness. In embodiments, a method of fabricating a semiconductor device includes graduating a gate metal thickness between a source end and drain end by non-uniformly recessing the first gate metal within the first opening relative to the surrounding dielectric.

A semiconductor device and a method of fabricating the same, the semiconductor device includes a substrate, a first gate and a second gate. The first gate is disposed on the substrate and includes a first gate insulating layer, a polysilicon layer, a silicide layer and a protective layer stacked with each other on the substrate and a first spacer surrounds the first gate insulating layer, the polysilicon layer, the silicide layer and the protective layer. The second gate is disposed on the substrate and includes a second gate insulating layer, a work function metal layer and a conductive layer stacked with each other on the substrate, and a second spacer surrounds the second gate insulating layer, the work function metal layer and the conductive layer.

First, second, and third trenches are formed in a layer over a substrate. The third trench is substantially wider than the first and second trenches. The first, second, and third trenches are partially filled with a first conductive material. A first anti-reflective material is coated over the first, second, and third trenches. The first anti-reflective material has a first surface topography variation. A first etch-back process is performed to partially remove the first anti-reflective material. Thereafter, a second anti-reflective material is coated over the first anti-reflective material. The second anti-reflective material has a second surface topography variation that is smaller than the first surface topography variation. A second etch-back process is performed to at least partially remove the second anti-reflective material in the first and second trenches. Thereafter, the first conductive material is partially removed in the first and second trenches.