An approach for utilizing an IC (integrated circuit) that is capable of storing multi-bit in storage is disclosed. The approach leverages the use of multiple nanowires structures as channels in a gate of a transistor. The use of multiple nanowires as channels allows for different V.sub.t (i.e., voltage of device) to be dependent on the thickness of the fe (ferroelectric layer) that surrounds each of the nanowire channels. Memory window is about 2d (thickness of a fe layer). Setting voltage is also proportional to the fe layer thickness. The V.sub.t of the device is the superposition of the various fe layers. For example, if there are three channels with three different Fe layer (of varying thickness), then four memory states can be achieved. More states can be achieved based on the number of channels in the device.

A method of manufacturing a semiconductor device includes forming a gate structure over an active region of a substrate, the gate structure comprising a first section and a second section. The first section and the second section dividing the active region into a first source/drain region between the first section and the second section, and a pair of second source/drain regions arranged on opposite sides of the gate structure. The method further includes forming a conductive field plate over the substrate, the field plate extending between the first section and the second section and overlapping an edge of the active region. The method further includes implanting a first well in the substrate, wherein the first well overlaps the edge of the active region. The method further includes forming an isolation structure in the substrate, wherein the conductive field plate extends over the isolation structure.

A gate electrode is formed on a semiconductor substrate between an n-type source region and an n-type drain region via a first insulating film. The first insulating film has second and third insulating films adjacent to each other in a plan view and, in a gate length direction of the gate electrode, the second insulating film is located on an n-type source region side, and the third insulating film is located on an n-type drain region side. The second insulating film is thinner than the third insulating film. The third insulating film is made of a laminated film having a first insulating film on the semiconductor substrate, a second insulating film on the first insulating film, and a third insulating film on the second insulating film, and each bandgap of the three insulating films is larger than that of the second insulating film.

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 transistor structure includes a gate conductive region, a gate dielectric region, a channel region and a drain region. The gate conductive region is below an original surface of a substrate. The gate dielectric region surrounds the gate conductive region. The channel region surrounds the gate dielectric region. The drain region is horizontally spaced apart from the gate conductive region, wherein the drain region includes a highly doped region; wherein the gate dielectric region includes a first dielectric portion and a second dielectric portion, the first dielectric portion is positioned between the gate conductive region and the highly doped region, and the second dielectric portion is positioned between the gate conductive region and the channel region; wherein a horizontal thickness of the first dielectric portion is greater than that of the second dielectric portion.

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.

A semiconductor device, a semiconductor device manufacturing method, and an image capturing device capable of suppressing variations in transistor characteristics. The semiconductor device includes a semiconductor substrate, and a field effect transistor. The field effect transistor includes a semiconductor region having a channel, a gate electrode covering the semiconductor region, and a gate insulating film. The semiconductor region has a top face, and a first side face at one side of the top face in a gate width direction of the gate electrode. The gate electrode has a first part facing the top face over the gate insulating film, and a second part facing the first side face over the gate insulating film. A first end face of the first part and a second end face of the second part are flush at at least one end of the gate electrode in a gate length direction.

A semiconductor device with an active transistor cell comprising a p-doped first and second base layers, surrounding an n type source region, the device further comprising a plurality of first gate electrodes embedded in trench recesses, has additional fortifying p-doped layers embedding the opposite ends of the trench recesses. The additional fortifying layers do not affect the active cell design in terms of cell pitch i.e., the design rules for transistor cell spacing, or hole drainage between the transistor cells, but reduce the gate-collector parasitic capacitance of the semiconductor, hence leading to optimum low conduction and switching losses. To further reduce the gate-collector capacitance, the trench recesses embedding the first gate electrodes can be formed with thicker insulating layers in regions that do not abut the first base layers, so as not to negatively impact the value of the threshold voltage.

A semiconductor device includes a first electrode, a second electrode, a semiconductor layer that includes a first semiconductor region, a second semiconductor region, and a third semiconductor region, a third electrode, a first insulating region, a second insulating region, a fourth electrode that has a plurality of portions consecutive in a first direction, the plurality of portions including a first portion that has a first width in a second direction, a second portion that is located closer to the second electrode than the first portion in the first direction and has a second width smaller than the first width in the second direction, and a third portion that is adjacent to the second portion, located closer to the second electrode than the second portion in the first direction, and has a third width larger than the second width in the second direction, and a third insulating region.

The present disclosure relates to a semiconductor device and a method of forming the same, and the semiconductor device includes a substrate, a gate line and a stress layer. The substrate has a plurality of first fins protruded from the substrate. The gate line is disposed over the substrate, across the first fins, to further include a gate electrode and a gate dielectric layer, wherein the dielectric layer is disposed between the gate electrode layer and the first fins. The stress layer is disposed only on lateral surfaces of the first fins and on a top surface of the substrate, wherein a material of the stress layer is different from a material of the first fins.