A power semiconductor device (1) comprises a gate-commutated thyristor cell (20) including a cathode electrode (2), a cathode region (9) of a first conductivity type, a base layer (8) of a second conductivity type, a drift layer (7) of the first conductivity type, an anode layer (5) of the second conductivity type, an anode electrode (3) and a gate electrode (4). The base layer (8) comprises a cathode base region (81) located between the cathode region (9) and the drift layer (7) and having a first depth (D1), a gate base region (82) located between the gate electrode (4) and the drift layer (7) and having a second depth (D2), and an intermediate base region (83) located between the cathode base region (81) and the gate base region (82) and having two different values of a third depth (D3) being between the first depth (D1) and the second depth (D2).

Fabrication methods and device structures for a silicon controlled rectifier. A cathode is arranged over a top surface of a substrate and a well is arranged beneath the top surface of the substrate. The cathode is composed of a semiconductor material having a first conductivity type, and the well also has the first conductivity type. A semiconductor layer, which has a second conductivity type opposite to the first conductivity type, includes a section over the top surface of the substrate. The section of the semiconductor layer is arranged to form an anode that adjoins the well along a junction.

A method of forming a semiconductor device includes forming a first vertical protection device comprising a thyristor in a substrate, forming a first lateral trigger element for triggering the first vertical protection device in the substrate, and forming an electrical path in the substrate to electrically couple the first lateral trigger element with the first vertical protection device.

A one-way switch has a gate referenced to a main back side electrode. An N-type substrate includes a P-type anode layer covering a back side and a surrounding P-type wall. First and second P-type wells are formed on the front side of the N-type substrate. An N-type cathode region is located in the first P-type well. An N-type gate region is located in the second P-type well. A gate metallization covers both the N-type gate region and a portion of the second P-type well. The second P-type well is separated from the P-type wall by the N-type substrate except at a location of a P-type strip that is formed in the N-type substrate and connects a portion on one side of the second P-type well to an upper portion of said P-type wall.

A clustered Insulated Gate Bipolar Transistor (CIGBT) comprising a drift region (24), a P region (20) formed within the n-type drift region, an N well region (22) formed within the P well region (20), a P base region (32) formed within the N well region (22) and a cathode region (36). One or more trenches (40) are formed in the device and configured to longitudinally intersect the drift region (24) and, optionally, the P well region (20) as well as laterally intersecting the base region (32), the N well region (22) and the P well region (20). An insulating film is formed on the inner surface of the trenches (40) and gate oxide is formed on the insulating film so as to substantially fill the trenches and form a gate.

There is provided a thyristor having emitter shorts, wherein in an orthogonal projection onto a plane parallel to a first main side, a contact area covered by an electrical contact of a first electrode layer with a first emitter layer and the emitter shorts includes areas in the shape of lanes, in which an area coverage of the emitter shorts is less than the area coverage of emitter shorts in the remaining area of the contact area, wherein the area coverage of the emitter shorts in a specific area is the area covered by the emitter shorts in that specific area relative to the specific area. The thyristor of the invention exhibits a fast turn-on process even without complicated amplifying gate structure.

A semiconductor device according to an embodiment includes a substrate, first and second pillar electrodes extending along a vertical direction substantially perpendicular to a surface of the substrate, and a plurality of memory cells disposed between the first and second pillar electrodes. Each of the plurality of memory cells includes first and second shared device layers that are disposed adjacent to the first and second pillar electrodes, respectively, and extend along the vertical direction, first and second base device layers disposed between the first and second shared device layers, and a control gate electrode disposed on one of the first and second base device layers. Both first and second base device layers are disposed on a plane over the substrate and substantially parallel to the surface of the substrate.

A triac has a vertical structure formed from a silicon substrate having an upper surface side. A main metallization on the upper surface side has a first portion resting on a first region of a first conductivity type formed in a layer of a second conductivity type. A second portion of the main metallization rests on a portion of the layer. A gate metallization on the upper surface side rests on a second region of the first conductivity type formed in the layer in the vicinity of the first region. A porous silicon bar formed in the layer at the upper surface side has a first end in contact with the gate metallization and a second end in contact with the main metallization.

A triac has a vertical structure formed from a silicon substrate having an upper surface side. A main metallization on the upper surface side has a first portion resting on a first region of a first conductivity type formed in a layer of a second conductivity type. A second portion of the main metallization rests on a portion of the layer. A gate metallization on the upper surface side rests on a second region of the first conductivity type formed in the layer in the vicinity of the first region. A porous silicon bar formed in the layer at the upper surface side has a first end in contact with the gate metallization and a second end in contact with the main metallization.

A bidirectional power semiconductor device with full turn-off control in both current directions and improved electrical and thermal properties is provided, the device comprises a plurality of first gate commutated thyristor (GCT) cells and a plurality of second GCT cells alternating with each other, a first base layer of each first GCT cell is separated from a neighbouring second anode layer of a neighbouring second GCT cell by a first separation region, and a second base layer of each second GCT cell is separated from a neighbouring first anode layer of a neighbouring first GCT cell by a second separation region.