A semiconductor device includes: a chip having a main surface; a first conductive type first region formed on a surface layer portion of the main surface; a second conductive type second region formed on a surface layer portion of the first region; a drain region formed on a surface layer portion of the second region; a source region formed on the surface layer portion of the first region at a distance from the second region; and a second conductive type floating region formed in the first region at a thickness position between a bottom portion of the first region and a bottom portion of the second region and being spaced apart from the bottom portion of the second region, wherein the floating region faces the second region with a portion of the first region interposed between the floating region and the second region.

A semiconductor device includes a semiconductor substrate, a gate dielectric, a gate electrode, and a pair of source/drain regions. The gate dielectric is disposed in the semiconductor substrate having an upper boundary lower than an upper surface of the semiconductor substrate, and an upper surface flush with the upper surface of the semiconductor substrate. The gate electrode is disposed over the gate dielectric having a first section over the upper boundary of the gate dielectric and a second section over the upper surface of the gate dielectric. The second section partially covers and partially exposes the upper surface of the gate dielectric. The pair of source/drain regions are disposed on opposing sides of the gate dielectric.

An integrated circuit (IC) device comprises a high voltage semiconductor device (HVSD) on a frontside of a semiconductor body and further comprises an electrode on a backside of the semiconductor body opposite the frontside. The HVSD may, for example, be a transistor or some other suitable type of semiconductor device. The electrode has one or more gaps directly beneath the HVSD. The one or more gaps enhance the effectiveness of the electrode for improving the breakdown voltage of the HVSD.

A semiconductor device includes a substrate, a gate structure, source and drain regions, and first and second lightly doped drain (LDD) regions. The source and drain regions are spaced apart and formed in an active region of the substrate at opposite sides of the gate structure. The first LDD region surrounds one side surface and a bottom surface of the drain region and has a first junction depth. The second LDD region surrounds one side surface and a bottom surface of the source region and has a second junction depth less than the first junction depth. The gate structure includes a gate dielectric layer, a gate electrode, and gate spacers respectively disposed on opposite side walls of the gate dielectric layer and the gate electrode. One side wall of the gate dielectric layer and electrode is aligned with one side surface of the first LDD region.

An IC includes a first and second active areas (AA) with a second conductivity type, a source and drain region, and an LDD extension to the source and drain in the first AA having a first conductivity type. A first bent-gate transistor includes a first gate electrode over the first AA extending over the corresponding LDD. The first gate electrode includes an angled portion that crosses the first AA at an angle of 45° to 80°. A second transistor includes a second gate electrode over the second AA extending over the corresponding LDD including a second gate electrode that can cross an edge of the second AA at an angle of about 90°. A first pocket distribution of the second conductivity type provides a pocket region under the first gate electrode. A threshold voltage of the first bent-gate transistor is ≥30 mV lower as compared to the second transistor.

The present disclosure relates to semiconductor structures and, more particularly, to field effect transistors and methods of manufacture. The structure includes: at least one gate structure comprising source/drain regions; and at least one isolation structure perpendicular to the at least one gate structure and within the source/drain regions.

A switching LDMOS device is formed first well in a semiconductor substrate that includes an LDD region and a first body doped region; a first heavily doped region serving as a source region is provided in the LDD region, and a second heavily doped region serving as a drain region is provided in the first body doped region; a channel of the switching LDMOS device is formed at a surface layer of the semiconductor substrate between the LDD region and the body doped region and below the gate structure; and one side of the LDD region and one side of the body doped region which are away from the gate structure both are provided with a field oxide or STI, and one side of the field oxide or STI is in contact with the first heavily doped region or the second heavily doped region.

In semiconductor device, a field plate portion having a high concentration p-type semiconductor region, a low concentration p-type semiconductor region having a lower impurity concentration than the high concentration p-type semiconductor region and a high concentration n-type semiconductor region is provided. Then, the high concentration p-type semiconductor region is electrically connected to the source region while the high concentration n-type semiconductor region is electrically connected to the drain region.

A method for manufacturing a semiconductor product is provided. The method comprises forming a semiconductor device within a wafer utilizing a predetermined number of masks. The method further comprises forming a first low-leakage semiconductor device within the wafer utilizing a first set of additional masks. The first low-leakage semiconductor device has a lower leakage current than that of the semiconductor device.

Structures for an extended-drain metal-oxide-semiconductor device and methods of forming a structure for an extended-drain metal-oxide-semiconductor device. The structure includes a substrate, a source region and a drain region in the substrate, a buffer dielectric layer positioned on the substrate adjacent to the drain region, and a gate electrode laterally positioned between the source region and the drain region. The gate electrode includes a portion that overlaps with the buffer dielectric layer, and the portion of the gate electrode includes notches.