According to one embodiment, a hydrogen concentration of a bottom part in a vicinity of a boundary with the insulating layer in the first silicon layer is higher than a hydrogen concentration of a part above the bottom part in the first silicon layer. And a resistivity of the bottom part in the first silicon layer is lower than a resistivity of the part above the bottom part in the first silicon layer.

A lateral insulated gate bipolar transistor, comprising: a substrate (100), having a first conductivity type; an insulating layer (200), formed on the substrate (100); an epitaxial layer (300), having a second conductivity type and formed on the insulating layer (200); a field oxide layer (400), formed on the epitaxial layer (300); a first well (500), having the first conductivity type; a plurality of gate trench structures (600); second source doped regions (720), having the second conductivity type; first source doped regions (710), having the first conductivity type; a second well (800), having the second conductivity type; a first drain doped region (910), having the first conductivity type and formed on a surface layer of the second well (800); gate lead-out ends (10); a source lead-out end (20); a drain lead-out end (30).

A semiconductor device includes a semiconductor layer having a first principal surface on one side thereof and a second principal surface on the other side thereof, a channel region of a first conductivity type formed at a surface layer portion of the first principal surface of the semiconductor layer, an emitter region of a second conductivity type formed at a surface layer portion of the channel region in the semiconductor layer, a drift region of the second conductivity type formed in a region of the second principal surface side with respect to the channel region in the semiconductor layer so as to be electrically connected to the channel region, a collector region of the first conductivity type formed at a surface layer portion of the second principal surface of the semiconductor layer so as to be electrically connected to the drift region, a cathode region of the second conductivity type formed at a surface layer portion of the second principal surface of the semiconductor layer so as to be electrically connected to the drift region and including a continuously laid around line-shaped pattern, and a gate electrode formed at the first principal surface side of the semiconductor layer so as to face the channel region across an insulating film.

A power semiconductor device is disclosed. The device includes a semiconductor body coupled to a first load terminal structure and a second load terminal structure, a first cell and a second cell. A first mesa is included in the first cell, the first mesa including: a first port region and a first channel region. A second mesa included in the second cell, the second mesa including a second port region. A third cell is electrically connected to the second load terminal structure and electrically connected to a drift region. The third cell includes a third mesa comprising: a third port region, a third channel region, and a third control electrode.

A semiconductor device including a first conductivity type substrate, a first conductivity type carrier store layer formed on an upper surface side of the substrate, a second conductivity type channel dope layer formed on the carrier store layer, a first conductivity type emitter layer formed on the channel dope layer, a gate electrode in contact with the emitter layer, the channel dope layer and the carrier store layer via a gate insulating film, and a second conductivity type collector layer formed on a lower surface side of the substrate, wherein the gate insulating film has a first part in contact with the emitter layer and the channel dope layer, a second part in contact with the carrier store layer, and a third part in contact with the substrate, and at least a part of the second part is thicker than the first part and the third part.

A method of manufacturing a semiconductor device includes forming an auxiliary mask including a plurality of mask openings on a main surface of a crystalline semiconductor substrate. A porous structure is formed in the semiconductor substrate. The porous structure includes a porous layer at a distance to the main surface and porous columns that extend from the porous layer into direction of the main surface and that are laterally separated from each other by a non-porous portion. A non-porous device layer is formed on the non-porous portion and on the porous columns.

An integrated circuit includes an insulating layer overlying a semiconductor substrate. A semiconductor layer of a first conductivity type overlies the insulating layer. A plurality of projecting regions that are spaced apart from each other overly the semiconductor layer. A sequence of PN junctions are in the semiconductor layer. Each PN junction is located at an edge of an associated projecting region. Each PN junction also extends vertically from an upper surface of the semiconductor layer to the insulating layer.

A semiconductor device includes an electrically conductive lead frame which includes a die pad and a plurality of electrically conductive leads, each of the leads in the plurality being spaced apart from the die pad. The semiconductor device further includes first and second integrated switching devices mounted on the die pad, each of the first and second integrated switching devices include electrically conductive gate, source and drain terminals. The source terminal of the first integrated switching device is disposed on a rear surface of the first integrated switching device that faces and electrically connects with the die pad. The drain terminal of the second integrated switching device is disposed on a rear surface of the second integrated switching device that faces and electrically connects with the die pad.

A power semiconductor device includes trenches disposed in a first base layer of a first conductivity type at intervals to partition main and dummy cells, at a position remote from a collector layer of a second conductivity type. In the main cell, a second base layer of the second conductivity type, and an emitter layer of the first conductivity type are disposed. In the dummy cell, a buffer layer of the second conductivity type is disposed. A gate electrode is disposed, through a gate insulating film, in a trench adjacent to the main cell. A buffer resistor having an infinitely large resistance value is inserted between the buffer layer and emitter electrode. The dummy cell is provided with an inhibiting structure to reduce carriers of the second conductivity type to flow to and accumulate in the buffer layer from the collector layer.

A semiconductor device includes a semiconductor layer having a first principal surface on one side thereof and a second principal surface on the other side thereof, a channel region of a first conductivity type formed at a surface layer portion of the first principal surface of the semiconductor layer, an emitter region of a second conductivity type formed at a surface layer portion of the channel region in the semiconductor layer, a drift region of the second conductivity type formed in a region of the second principal surface side with respect to the channel region in the semiconductor layer so as to be electrically connected to the channel region, a collector region of the first conductivity type formed at a surface layer portion of the second principal surface of the semiconductor layer so as to be electrically connected to the drift region, a cathode region of the second conductivity type formed at a surface layer portion of the second principal surface of the semiconductor layer so as to be electrically connected to the drift region and including a continuously laid around line-shaped pattern, and a gate electrode formed at the first principal surface side of the semiconductor layer so as to face the channel region across an insulating film.