Semiconductor structures and fabrication processes are provided. A semiconductor according to the present disclosure includes a first region including a first fin, a second fin, and a third fin extending along a first direction, and a second region abutting the first region. The second region includes a fourth fin and a fifth fin extending along the first direction. The first fin is aligned with the fourth fin and the second fin is aligned with the fifth fin. The third fin terminates at an interface between the first region and the second region.

An RC IGBT includes: an active region with separate IGBT and diode sections; a semiconductor body forming a part of the active region; a first load terminal and control terminal at a first side of the body and a second load terminal at a second side, the control terminal including a control terminal finger that laterally overlaps, in the active region, with the diode section. Control trenches extending into the semiconductor body along a vertical direction have a control trench electrode electrically connected to the control terminal for controlling a load current between the load terminals in the IGBT section. At least one control trench extends into both IGBT and diode sections. The electrical connection between the control trench electrode of that control trench and the control terminal is established at least based on an electrically conductive member arranged, in the diode section, in contact with the control terminal finger.

A semiconductor device is provided. The semiconductor device includes a bottom source/drain; a top source/drain; a fin provided between the bottom source/drain and the top source/drain, the fin including a first fin structure and a second fin structure that are symmetric to each other in a plan view. Each of the first and second fin structures includes a main fin extending laterally in a first direction, and first and second extension fins extending laterally from the main fin in a second direction perpendicular to the first direction. The main fin extends laterally in the first direction beyond where the first and second extension fins connect to the main fin.

A level shifter circuit for translating input signal to output signal is disclosed. The level shifter includes an input stage and a latch stage. The latch stage comprises at least a transistor characterized in a substantially matched transconductance with the input stage for preventing a discrete realization of a voltage clamp circuit. The transistor is a semiconductor device including a source region having a source doping region and a drain region having a first doping region and a second doping region. The first doping region is doped with a first conductivity impurity. The second doping region is disposed around the first doping region so as to surround the first doping region, and is doped with a second conductivity impurity. The second doping region has a higher on-resistance than the first doping region, thereby a high resistive series path is created by the second doping region to mimic an embedded resistor.

A semiconductor device and a method for manufacturing same are provided. A semiconductor device includes: an active area located in a semiconductor substrate and including a central area and a peripheral area surrounding the central area; a first strained layer formed in the peripheral area in an embedded manner, and including at least a first sub-portion, a second sub-portion, a third sub-portion, and a fourth sub-portion, where the first sub-portion and the third sub-portion are separately arranged on two sides of the central area in first direction, and the second sub-portion and the fourth sub-portion are separately arranged on the other two sides of the central area in second direction; and a gate located on the active area, extending in a first direction and covering at least a part of the central area, at least a part of the first sub-portion, and at least a part of the third sub-portion.

A semiconductor device is proposed. The semiconductor device includes a semiconductor substrate including a RC-IGBT with a diode area. The diode area includes a p-doped anode region and an n-doped emitter efficiency adjustment region. At least one of the p-doped anode region or the n-doped emitter efficiency adjustment region includes deep level dopants.

Field plate structures for gallium nitride (GaN) high voltage transistors are disclosed. In one aspect, a transistor includes a GaN substrate, a source region formed on the GaN substrate, a drain region formed on the GaN substrate and separate from the source region, a gate region formed between the source region and the drain region, a pedestal formed on the GaN substrate and positioned between the gate region and the drain region, and a field plate electrically coupled to the source region, where the field plate extends from a proximal region positioned between the source region and the pedestal, towards the drain region, where at least a portion of the field plate overlaps at least a portion of the pedestal.

A semiconductor device includes a semiconductor layer, a source region and a drain region that are formed in the semiconductor layer and at an interval in a first direction, a gate insulating film that is formed such as to cover a channel region between the source region and the drain region, and a gate electrode that is formed on the gate insulating film and opposes the channel region across the gate insulating film. The gate insulating film has a major portion on which the gate electrode is formed and extension portions projecting outward from each of both sides of the major portion in a second direction orthogonal to the first direction and leak current suppressing electrodes are formed on the extension portions.

A semiconductor device includes a first nitride-based semiconductor layer, a second nitride-based semiconductor layer, a pair of first electrodes, a second electrode, a doped nitride-based semiconductor layer, and a pair of gate electrodes. The second nitride-based semiconductor layer is disposed on the first nitride-based semiconductor layer. The first and second nitride-based semiconductor layers collectively have an active portion and an electrically isolating portion that is non-semi-conducting and surrounds the active portion to form an interface therebetween. The first electrodes are disposed over the second nitride-based semiconductor layer. The second electrode are disposed over the second nitride-based semiconductor layer and between the first electrodes. The doped nitride-based semiconductor layer is disposed over the second nitride-based semiconductor layer and between the first electrodes and surrounding the second electrode. The gate electrodes are disposed over the doped nitride-based semiconductor layer and located at opposite sides of the second electrode.

A power semiconductor device includes, an active area that conducts load current between first and second load terminal structures, a drift region, and a backside region that includes, inside the active area, first and second backside emitter zones one or both of which includes: first sectors having at least one first region of a second conductivity type contacting the second load terminal structure and a smallest lateral extension of at most 50 μm; and/or second sectors having a second region of the second conductivity type contacting the second load terminal structure and a smallest lateral extension of at least 50 μm. The emitter zones differ by at least of: the presence of first and/or second sectors; smallest lateral extension of first and/or second sectors; lateral distance between neighboring first and/or second sectors; smallest lateral extension of the first regions; lateral distance between neighboring first regions within the same first sector.