A gate-turn-off thyristor is provided. The gate-turn-off thyristor includes a plurality of strips formed by repeatedly arranging a plurality of N-type emitter regions with high doping concentration of an upper transistor on an upper surface of an N-type silicon substrate with high resistivity, wherein a periphery of each strip of the plurality of strips is surrounded with a P-type dense base region bus bar of the upper transistor, a cathode metal layer is disposed on an N-type emitter region of the plurality of N-type emitter regions of the upper transistor, and a P-type base region of the upper transistor is disposed below the N-type emitter region of the upper transistor; a side of the P-type base region of the upper transistor is connected to a P-type dense base region of the upper transistor or a P-type dense base region bus bar of the upper transistor.

Substrate-less silicon controlled rectifier (SCR) integrated circuit structures, and methods of fabricating substrate-less silicon controlled rectifier (SCR) integrated circuit structures, are described. For example, a substrate-less integrated circuit structure includes a first fin portion and a second fin portion that meet at a junction. A plurality of gate structures is over the first fin portion and a second fin portion. A plurality of P-type epitaxial structures and N-type epitaxial structures is between corresponding adjacent ones of the plurality of gate structures. Pairs of the P-type epitaxial structures alternate with pairs of the N-type epitaxial structures.

A MOS controlled thyristor device according to the concept of the present invention includes a substrate comprising a first surface and a second surface, which face each other, gate patterns disposed on the first surface, a cathode electrode configured to cover the gate patterns, and an anode electrode disposed on the second surface, The substrate includes a lower emitter layer having a first conductive type, a lower base layer having a second conductive type on the lower emitter layer, an upper base region provided in an upper portion of the lower emitter layer and having a first conductive type, wherein the upper base region is configured to expose a portion of a top surface of the lower base layer, an upper emitter region having a second conductive type and provided in an upper portion of the upper base region, a first doped region having a first conductive type and a second doped region surrounded by the first doped region and having a second conductive type, wherein the first and second doped regions are provided in an upper portion of the upper emitter region, and a first doping pattern having a first conductive type, which is provided on one surface of the upper portion of the upper emitter region. The first doping pattern is interposed between the upper base region and the first doped region along a first direction parallel to the top surface of the substrate. The first doping pattern is configured to expose a top surface of the upper emitter region on the other surface of the upper portion of the upper emitter region. Each of the gate patterns is configured to cover portions of an exposed top surface of the lower base layer, an exposed top surface of the upper base layer, an exposed top surface of the upper emitter region, a top surface of the first doping pattern, and a top surface of the first doped region. The cathode electrode is configured to cover portions of top and side surfaces of the gate pattern, a top surface of the second doped region, and a top surface of the first doped region. The first conductive type and the second conductive type are different from each other.

A short-circuit semiconductor component comprises a semiconductor body, in which a rear-side base region of a first conduction type, an inner region of a second complementary conduction type, and a front-side base region of the first conduction type are disposed. The rear-side base region is electrically connected to a rear-side electrode, and the front-side base region is electrically connected to a front-side electrode. A turn-on structure, which is an emitter structure of the second conduction type, is embedded into the front-side base region and/or rear-side base region and is covered by the respective electrode and is electrically contacted with the electrode placed on the base region respectively embedding it. It can be turned on by a trigger structure which can be activated by an electrical turn-on signal. In the activated state, the trigger structure injects an electrical current surge into the semiconductor body, which irreversibly destroys a semiconductor junction.

An integrated gate-commutated thyristor (IGCT) includes a semiconductor wafer having a first main side and a second main side opposite to the first main side and a plurality of first type thyristor cells and second type thyristor cells. The cathode electrode of the first type thyristor cells forms an ohmic contact with the cathode region and the cathode electrode of the second type thyristor cells is insulated from the cathode region. A predefined percentage of second type thyristor cells of the overall amount of first type thyristor cells and second type thyristor cells in a segment ring is greater than .sub.0% and less than or equal to 75%.

Protection against electrostatic discharges is to be improved for electronic devices, or is to be provided in the first place. The device for protection against electrostatic discharges having an integrated semiconductor protection device comprises an inner region (1) configured at least as a thyristor (SCR) and at least one outer region (2a, 2b) configured as a corner region, which is formed and configured at least as a PNP transistor. The inner region (1) and the at least one outer region (2a, 2b) are arranged adjacent to one another.

A short-circuit semiconductor component comprises a semiconductor body, in which a rear-side base region of a first conduction type, an inner region of a second conduction type complementary to the first conduction type, and a front-side base region of the first conduction type are disposed. The rear-side base region is electrically connected to a rear-side electrode with a rear-side electrode width, and the front-side base region is electrically connected to a front-side electrode with a front-side electrode width. A turn-on structure with a turn-on structure width is embedded into the front-side and/or rear-side base region and is covered by the respective electrode. The turn-on structure is configured to be turned on depending on a supplied turn-on signal and to produce, on a one-off basis, an irreversible, low-resistance connection between the two electrodes. The ratio of the turn-on structure width to the respective electrode width is less than 1.

An ESD protection structure formed within a semiconductor substrate of an integrated circuit device. The ESD protection structure comprises a thyristor structure being formed from a first P-doped section forming an anode of the thyristor structure, a first N-doped section forming a collector node of the thyristor structure, a second P-doped section, and a second N-doped section forming a cathode of the thyristor structure. A low-resistance coupling is provided between an upper surface region of the collector node of the thyristor structure and the anode of the thyristor structure.

The present application provides an insulated gate bipolar transistor (IGBT) device with narrow mesa and a manufacture thereof. The device comprises: a semiconductor substrate; gate trench structures and emitter trench structures formed on front surface of the semiconductor substrate and alternately arranged along with horizontal direction; wherein the gate trench structures and the emitter trench structures are respectively set in pair along with the arrangement direction, and the pairs of the gate trench structures and the pairs of the emitter trench structures are set in alternate arrangement along with the arrangement direction; well regions formed between the emitter trench structures of one pair; emitter injection regions formed between the gate trench structures of one pair and between the emitter trench structures of one pair, respectively; and wherein, in the region between the emitter trench structures of the one pair, the emitter injection region is above the well region.

A thyristor, in particular a phase control thyristor, is disclosed with comprises: a) a semiconductor slab, in particular a semiconductor wave or die, in which a thyristor structure is formed, b) a cathode metallization formed on a cathode region on a cathode side surface of the semiconductor slab, c) a gate metallization formed on a gate region on the cathode side surface of the semiconductor slab, d) a plurality of N discrete emitter shorts, arranged at points P.sub.i in the cathode region, said points having point locations x.sub.i, with iε{1; . . . ; N}, e) the points P.sub.l defining a Delaunay triangulation comprising a plurality of triangles T.sub.j with jε{1; . . . ; M), wherein f) for a first subset of triangles T.sub.l with lεS.sub.1⊂{1; . . . ; M), g) with each triangle T.sub.l being characterized by a geometric quantity having values q.sub.T,l with lεS.sub.1⊂{1; . . . ; M), said geometric quantity having a mean value μ, and i) a coefficient of variation of the values q.sub.T,l with lεS.sub.1 is smaller than 0.1, preferably smaller than 0.05, and/or ii) an absolute value of a skewedness of the geometric quantities q.sub.T,l with lεS.sub.1 is smaller than 5, preferably smaller than 1, and/or iii) a Kurtosis of the geometric quantities q.sub.T,l with lεS.sub.1 is smaller than 20, preferably smaller than 10, and h) for a second subset of triangles T.sub.m with mεS.sub.2⊂S.sub.1, for which the respective geometric quantities q.sub.T,m with mεS.sub.2 deviate from the mean value by more than a predetermined amount, in particular by more than 30%, (1) a quotient of a standard deviation of the quantities q.sub.T,m with mεS.sub.2 and a mean squared value of the geometric quantity q.sub.T,l with lεS.sub.1 is less than 1 or less than 0.1, and/or a quotient of a number of triangles in the second subset and a number of triangles in the first subset is less than