An apparatus includes a substrate; a group III-Nitride buffer layer on the substrate; a group III-Nitride barrier layer on the group III-Nitride buffer layer, the group III-Nitride barrier layer may include a higher bandgap than a bandgap of the group III-Nitride buffer layer; a source electrically coupled to the group III-Nitride barrier layer; a gate electrically coupled to the group III-Nitride barrier layer; a drain electrically coupled to the group III-Nitride barrier layer; and a conductive metallic region being at least one of the following: in the substrate or on the substrate below said group III-Nitride barrier layer. Additionally, the conductive metallic region is structured and arranged to extend a limited length parallel to said group III-Nitride barrier layer.

In order to improve productivity of a semiconductor device, while improving stability of the blocking voltage of the semiconductor device, this semiconductor device is characterized by having a semiconductor element, and a laminated structure having three resin layers, said laminated structure being in a peripheral section surrounding a main electrode on one surface of the semiconductor element. The semiconductor device is also characterized in that the laminated structure has, on the center section side of the semiconductor element, a region where a lower resin layer is in contact with an intermediate resin layer, and a region where the lower resin layer is in contact with an upper resin layer.

Provided is a power semiconductor device comprising a gate electrode in a trench of a substrate; a body region having a first conductivity type on one side of the gate electrode; a source region having a second conductivity type adjacent to the gate electrode; a floating region having a first conductivity type on the other side of the gate electrode; an edge doped region having a first conductivity type spaced apart from the floating region and electrically connected to the source region; an edge junction isolation region having a second conductivity type between the floating region and the edge doped region; and a drift region having a second conductivity type below the floating, edge doped, and edge junction isolation regions, wherein the doping concentration of a second conductivity type in the edge junction isolation region is higher than the doping concentration of a second conductivity type in the drift region.

A semiconductor device is disclosed that includes a first region of a first conductivity type that includes a drain, a region of a second conductivity type abutting the first region in a lateral direction and a vertical direction to form an interface between the first conductivity type and the second conductivity type, wherein the drain region is spaced apart from the interface. A source region of the first conductivity type abuts the second region in the lateral direction and vertical directions. A control gate structure includes a conductive layer that is spaced apart from the drain region by a first dimension in the lateral direction. A shallow trench isolation (STI) region having a second dimension in the lateral direction is disposed at a location of the first region between the source and drain regions, wherein the second dimension is less than one-half of the first dimension.

A semiconductor device includes a first conductive type semiconductor layer which has a principal surface, a second conductive type well region which demarcates an active region and an outer region on the principal surface and is formed on a surface layer portion of the principal surface and includes a high concentration portion high in impurity concentration on the active region side and includes a low concentration portion lower in impurity concentration than the high concentration portion on the outer region side, and a second conductive type impurity region of the active region which is formed on a surface layer portion of the principal surface.

A semiconductor device includes a transistor cell region, and a first termination region devoid of transistor cells. The transistor cell region includes a gate structure, a plurality of needle-shaped first field plate structures, body regions of a second conductivity type, and source regions of a first conductivity type. The first termination region surrounds the transistor cell region and includes needle-shaped second field plate structures. The needle-shaped first field plate structures are arranged in a first pattern and the needle-shaped second field plate structures are arranged in a second pattern.

In an edge termination region, p-type regions and p.sup.−-type regions configuring a spatial modulation JTE structure are selectively provided at depth positions apart from a front surface of a semiconductor substrate. Respective bottoms of the p-type regions and the p.sup.−-type regions are at depth positions deeper from the front surface of the semiconductor substrate than is a bottom of a p-type peripheral region of a peripheral portion of an active region. An outer-side corner of the bottom of the p-type peripheral region is surrounded by an innermost one of the p-type regions and is free from contact with an n.sup.−-type drift region of the edge termination region.

A semiconductor device of the present invention achieves improved avoidance of a parasitic operation in a circuit region while achieving miniaturization of the semiconductor device and a reduction in the amount of time for manufacturing the semiconductor device. The semiconductor device according to the present invention includes an IGBT disposed on a first main surface of a semiconductor substrate provided with a drift layer of a first conductivity type; a thyristor disposed on the first main surface of the semiconductor substrate; a circuit region; a hole-current retrieval region separating the IGBT and the circuit region in a plan view; and a diffusion layer of a second conductivity type, the diffusion layer being disposed on a second main surface of the semiconductor substrate. The IGBT has an effective area equal to or less than an effective area of the thyristor in a plan view.

In a step, acceptor ions are implanted from a back surface of a semiconductor substrate. In a step, a wet process of immersing the semiconductor substrate in a chemical solution including hydrofluoric acid is performed, to introduce hydrogen atoms into the semiconductor substrate. In a step, proton radiation is provided to the back surface of the semiconductor substrate, to introduce hydrogen atoms into the semiconductor substrate and form radiation-induced defects. In a step, an annealing process is performed on the semiconductor substrate, to form hydrogen-related donors by reaction of the hydrogen atoms and the radiation-induced defects and reduce the radiation-induced defects.

A layout of a semiconductor device stored on a non-transitory computer-readable medium includes a first transistor in an active device region, the first transistor comprising a first channel region a first source region and a first drain region. The layout further includes a second transistor in a guard ring region, the second transistor comprising a second channel region a second source region and a second drain region. The second channel region includes a semiconductor material having a higher thermal conductivity than a semiconductor material of the first channel region.