There is provided a semiconductor element containing gallium nitride. The semiconductor element includes a semiconductor layer including a first surface having a first region and a second region that is a projecting portion having a strip shape and projecting relative to the first region or a recessed portion having a strip shape and being recessed relative to the first region. Of the first surface, at least one of surfaces of the first region and the second region includes a crystal plane having a plane orientation different from a (000-1) plane orientation and a (1-100) plane orientation.

An integrated circuit (IC) device includes a fin-type active region extending in a first lateral direction on a device region of a substrate. A gate line extends in a second lateral direction on the fin-type active region. The second lateral direction intersects with the first lateral direction. A source/drain region is adjacent to one side of the gate line on the fin-type active region. A gate contact is on the gate line and connected to the gate line. A source/drain contact is on the source/drain region and includes a first segment facing the gate contact and a second segment integrally connected to the first segment. The second segment extends from the first segment in the second lateral direction. In the first lateral direction, a first distance from the first segment to the gate line is greater than a second distance from the second segment to the gate line.

Various embodiments of the present disclosure are directed towards an integrated chip. The integrated chip includes a well region disposed within a semiconductor substrate and comprises a first doping type. A gate electrode overlies the well region. A first contact region is disposed within the well region and comprises a second doping type opposite the first doping type. A second contact region is disposed within the semiconductor substrate and laterally offset from the well region. The second contact region comprises the first doping type and the gate electrode is disposed between the first contact region and the second contact region. A gate dielectric layer is disposed between the semiconductor substrate and the well region, where a thickness of the gate dielectric layer is greater than about 140 Angstroms.

A heterojunction bipolar transistor includes: a substrate; a base mesa disposed on the substrate, wherein the base mesa includes a collector layer and a base layer disposed on the collector layer, and wherein in a top view, the base layer includes a first edge and a second edge opposite to the first edge; an emitter layer disposed on the base layer; a base electrode disposed on the substrate and connected to the base layer; a dielectric layer disposed on the base electrode, wherein a first via hole is formed in the dielectric layer at the first edge of the base layer, and a second via hole is formed in the dielectric layer at the second edge of the base layer; and a conductive feature disposed on the dielectric layer, wherein the conductive feature is connected to the base electrode through the first via hole and the second via hole.

A field-effect transistor for terahertz wave detection using a gate as an antenna includes a silicon substrate including a source and a drain formed outside a channel region surrounding the source, and a gate formed to be spaced apart from the silicon substrate and correspond to the channel region, on a dielectric layer formed on a surface of the silicon substrate, in which the drain has a width determined based on a first performance parameter associated with a terahertz wave reception rate of the field-effect transistor and the channel region has a width determined based on a second performance parameter associated with detection of a terahertz wave to be received by the field-effect transistor.

A semiconductor device is provided, which includes a substrate, a first and second doped wells, a drain and source regions, a gate structure, a field plate and a booster plate. The first and second doped wells are arranged in the substrate. The drain region is arranged in the first doped well and the source region is arranged in the second doped well. The gate structure is arranged over the substrate and between the source and drain regions. The field plate is arranged over the first doped well and the booster plate arranged between the field plate and the first doped well.

[Object] To provide a semiconductor device capable of improving a discharge starting voltage when measuring electric characteristics, and widening a pad area of a surface electrode or increasing the number of semiconductor devices (number of chips) to be obtained from one wafer, and a method for manufacturing the same.

[Solution Means] A semiconductor device 1 includes an n-type SiC layer 2 having a first surface 2A, a second surface 2B, and end faces 2C, a p-type voltage relaxing layer 7 formed in the SiC layer 2 so as to be exposed to the end portion of the first surface 2A of the SiC layer 2, an insulating layer 8 formed on the SiC layer 2 so as to cover the voltage relaxing layer 7, and an anode electrode 9 that is connected to the first surface 2A of the SiC layer 2 through the insulating layer 8 and has a pad area 95 selectively exposed.

A semiconductor device includes a transistor cell with a source region of a first conductivity type and a gate electrode. The source region is formed in a wide bandgap semiconductor portion. A diode chain includes a plurality of diode structures. The diode structures are formed in the wide bandgap semiconductor portion and electrically connected in series. Each diode structure includes a cathode region of the first conductivity type and an anode region of a complementary second conductivity type. A gate metallization is electrically connected with the gate electrode and with a first one of the anode regions in the diode chain. A source electrode structure is electrically connected with the source region and with a last one of the cathode regions in the diode chain.

A semiconductor device includes: a drift region of a first conductivity type arranged between first and second surfaces of a semiconductor body; a first region of the first conductivity type at the second surface; a second region of a second conductivity type arranged adjacent to the first region at the second surface, the second region including first and second sub-regions, the second sub-region arranged between the first sub-region and the second surface; and a first electrode on the second surface and arranged directly adjacent to the first region and the second sub-region. The first electrode is electrically connected to the drift region by the first region. The first sub-region protrudes, along a first lateral direction, over an interface or a separation region between the second sub-region and the first region. A part of the first region is confined by the first sub-region and the first electrode along a vertical direction.

Structures and related techniques for control of two-dimensional electron gas (2DEG) charge density in gallium nitride (GaN) devices are disclosed. In one aspect, a GaN device includes a compound semiconductor substrate, a source region formed in the compound semiconductor substrate, a drain region formed in the compound semiconductor substrate and separated from the source region, a 2DEG layer formed in the compound semiconductor substrate and extending between the source region and the drain region, a gate region formed on the compound semiconductor substrate and positioned between the source region and the drain region, and a plurality of isolated charge control structures disposed between the gate region and the drain region.