Abstract: Provided is a semiconductor device that includes a drift region that is of a first conductivity type and is provided in a semiconductor substrate; a base region that is of a second conductivity type and is provided above the drift region; an accumulation region that is of the first conductivity type provided between the base region and the drift region; and an electric field relaxation region that is provided between the base region and the accumulation region, wherein the boundary between the electric field relaxation region and the accumulation region is a location for a half-value for the peak of the doping concentration of the accumulation region, and an integrated concentration of the electric field relaxation region is greater than or equal to 5E14 cm?2 and less than or equal to 5E15 cm?2.

Abstract: A high-voltage device includes a first frame-like isolation and a second frame-like isolation separated from each other, a first frame-like gate structure covering the first frame-like isolation, a second frame-like gate structure covering the second frame-like isolation, a first drain region enclosed by the first frame-like isolation, a second drain region enclosed by the second frame-like isolation, a first frame-like source region surrounding the first frame-like gate structure, a second frame-like source region surrounding the second frame-like gate structure, a first doped region surrounding the first and second frame-like gate structures, and a second doped region disposed between the first and second frame-like gate structures. The first and second drain regions, and the first and second frame-like source regions include a first conductivity type. The first and the second doped region include a second conductivity type.

Abstract: There is provided a semiconductor device comprising: a semiconductor substrate including a drift region of a first conductivity type; an emitter region of the first conductivity type provided above the drift region inside the semiconductor substrate and having a doping concentration higher than the drift region; a base region of a second conductivity type provided between the emitter region and the drift region inside the semiconductor substrate; a first accumulation region of the first conductivity type provided between the base region and the drift region inside the semiconductor substrate and having a doping concentration higher than the drift region; a plurality of trench portions provided to pass through the emitter region, the base region and first accumulation region from an upper surface of the semiconductor substrate, and provided with a conductive portion inside; and a capacitance addition portion provided below the first accumulation region to add a gate-collector capacitance thereto.

Abstract: A semiconductor device that allows easy hole extraction is provided. The semiconductor device includes: a semiconductor substrate having drift and base regions; a transistor portion formed in the semiconductor substrate; and a diode portion formed adjacent to the transistor portion and in the semiconductor substrate. In the transistor portion and the diode portion: a plurality of trench portions each arrayed along a predetermined array direction; and a plurality of mesa portions formed between respective trench portions are formed, among the plurality of mesa portions, at least one boundary mesa portion at a boundary between the transistor portion and the diode portion includes a contact region at an upper surface of the semiconductor substrate and having a concentration higher than that of the base region, and an area of the contact region at the boundary mesa portion is greater than an area of the contact region at another mesa portion.

Abstract: In a semiconductor device according to an embodiment, ends of conductor portions are electrically connected to an overvoltage protection diode so that depletion occurs in a diffusion layer in a portion near an insulating film in a reverse bias application state, and/or ends of conductor portions are electrically connected to the overvoltage protection diode so that depletion occurs in a peripheral semiconductor region in a portion near the insulating film in the reverse bias application state.

Abstract: Various embodiments provide materials and methods for integrating exemplary heterostructure field-effect transistor (HFET) driver circuit or thyristor driver circuit with LED structures to reduce or eliminate resistance and/or inductance associated with their conventional connections.

Abstract: A power semiconductor device includes a four-layer structure having layers arranged in order: (i) a cathode layer of a first conductivity type with a central area being surrounded by a lateral edge, the cathode layer being in direct electrical contact with a cathode electrode, (ii) a base layer of a second conductivity type, (iii) a drift layer of the first conductivity typehaving a lower doping concentration than the cathode layer, and (iv) an anode layer of the second conductivity type which is in electrical contact with an anode electrode. The base layer includes a first layer as a continuous layer contacting the central area of the cathode layer. A resistance reduction layer, in which the resistance at the junction between the lateral edge of the cathode and base layers is reduced, is arranged between the first layer and the cathode layer and covers the lateral edge of the cathode layer.

Abstract: A memory cell includes a thyristor having a plurality of alternately doped, vertically superposed semiconductor regions; a vertically oriented access transistor having an access gate; and a control gate operatively laterally adjacent one of the alternately doped, vertically superposed semiconductor regions. The control gate is spaced laterally of the access gate. Other embodiments are disclosed, including methods of forming memory cells and methods of forming a shared doped semiconductor region of a vertically oriented thyristor and a vertically oriented access transistor.

Abstract: Provided is a semiconductor device including a substrate, and a first wiring layer, a second wiring layer, and a switch via formed on the substrate. The first wiring layer has first wiring formed therein and the second wiring layer has second wiring formed therein. The switch via connects the first wiring and the second wiring. The switch via includes at least at its bottom a switch element including a resistance change layer. A resistance value of the resistance change layer changes according to a history of an electric field applied thereto.

Abstract: An n+-emitter layer arranged under an emitter electrode is formed of convex portions arranged at predetermined intervals and a main body coupled to the convex portions. A convex portion region is in contact with the emitter electrode, and a p+-layer doped more heavily than a p-base layer is arranged at least below the emitter layer. In a power transistor of a lateral structure, a latch-up immunity of a parasitic thyristor can be improved, and a turn-off time can be reduced.

Abstract: An n+-emitter layer arranged under an emitter electrode is formed of convex portions arranged at predetermined intervals and a main body coupled to the convex portions. A convex portion region is in contact with the emitter electrode, and a p+-layer doped more heavily than a p-base layer is arranged at least below the emitter layer. In a power transistor of a lateral structure, a latch-up immunity of a parasitic thyristor can be improved, and a turn-off time can be reduced.

Abstract: An insulated gate type thyristor includes: a first current terminal semiconductor region of a first conductivity type having a high impurity concentration; a first base semiconductor region of a second conductivity type opposite to the first conductivity type having a low impurity concentration and formed on the first current terminal semiconductor region; a second base semiconductor region of the first conductivity type having a low impurity concentration and formed on the first base semiconductor region; a second current terminal semiconductor region of the second conductivity type having a high impurity concentration and formed on the second base semiconductor region; a trench passing through the second current terminal semiconductor region and entering the second base semiconductor region leaving some depth thereof, along a direction from a surface of the second current terminal semiconductor region toward the first base semiconductor region; and an insulated gate electrode structure formed in the trench.

Abstract: A structure of protection of a first area of a semiconductor wafer including a substrate of a first conductivity type against high-frequency noise likely to be injected from components formed in the upper portion of a second area of the wafer, includes a very heavily-doped wall of the first conductivity type having substantially the depth of the upper portion. The wall is divided into three heavily-doped strips of the first conductivity type separated and surrounded by medium-doped intermediary strips of the first conductivity type. The distance between the heavily-doped strips being of the order of magnitude of the substrate thickness.

Abstract: A thyristor and a method for manufacturing the thyristor that includes a gate region extending from the first major surface into a semiconductor substrate and an anode region extending from the second major surface into the semiconductor substrate. A cathode region extends into a portion of the gate region. Optionally, enhanced doped regions extend into the gate and anode regions. A mesa structure having a height HG is formed from the first major surface and a mesa structure having a height HA is formed from the second major surface. The gate region extends under the first major surface of the semiconductor substrate and it extends vertically into the semiconductor substrate a distance that is greater than height HG. The anode region extends under the second major surface of the semiconductor substrate and it extends vertically into the semiconductor substrate a distance that is greater than height HA.

Abstract: A semiconductor system includes a self arc-extinguishing device, and an IGBT that works as a thyristor when a current between a first terminal and a second terminal connected to a second well electrode is small, and as a bipolar transistor when that current is large, and automatically switches between them according to the magnitude of the current. The IGBT is formed with a first conductivity-type semiconductor substrate. On a surface layer of the substrate is a second conductivity-type well region to which a first well electrode is connected. A first conductivity-type emitter region, to which an emitter electrode is connected, is disposed on a surface layer in the well region. A control electrode is disposed through an insulating film partially covering the well and emitter regions. A second conductivity-type well layer, to which the second well electrode is connected, is disposed on a back surface side of the substrate.

Abstract: An IGBT with monolithic integrated antiparallel diode has one or more emitter short regions forming the diode cathode in the region of the high-voltage edge. The p-type emitter regions of the IGBT have no emitter shorts. The counterelectrode of the diode exclusively comprises p-type semiconductor wells on the front side of the device. Particularly in applications, such as lamp ballast, in which the diode of the IGBT is firstly forward-biased, hard commutation is not effected and the current reversal takes place relatively slowly. The emitter short regions may be strips or points below the high-voltage edge. The horizontal bulk resistance is increased and the snapback effect is reduced without reducing the robustness in the edge region. In a second embodiment, the IGBT is produced using thin wafer technology and the thickness of the substrate defining the inner zone is less than 200 ?m. The thickness of the emitter region or of the emitter regions and short region(s) is less than 1 ?m.