An integrated circuit includes a bipolar transistor, e.g. a back-ballasted NPN, that can conduct laterally and vertically. At a low voltage breakdown and low current conduction occur laterally near a substrate surface, while at a higher voltage vertical conduction occurs in a more highly-doped channel below the surface. A relatively high-resistance region at the surface has a low doping level to guide the conduction deeper into the collector.

A semiconductor device according to one or more embodiments may include a first semiconductor region of a first conductivity type, a second semiconductor region of the first conductivity type with a higher impurity concentration than an impurity concentration of the first semiconductor region, the second semiconductor region being provided on a first principal surface of the first semiconductor region, a third semiconductor region of a second conductivity type provided on an upper surface of the second semiconductor region, the third semiconductor region being doped with an impurity in accordance with an impurity concentration profile including peaks along a film thickness direction, a fourth semiconductor region of the first conductivity type provided on an upper surface of the third semiconductor region.

A semiconductor device (300) comprising: a doped semiconductor substrate (302); an epitaxial layer (304), disposed on top of the substrate, the epitaxial layer having a lower concentration of dopant than the substrate; a switching region disposed on top of the epitaxial layer; and a contact diffusion (350) disposed on top of the epitaxial layer, the contact diffusion having a higher concentration of dopant than the epitaxial layer; wherein the epitaxial layer forms a barrier between the contact diffusion and the substrate.

A semiconductor device includes a semiconductor substrate, multiple trench gate structures and an emitter region. The semiconductor substrate includes: a drift layer of a first conductivity type; a base layer of a second conductivity type disposed on the drift layer; and a collector layer of the second conductivity type, the collector layer disposed at a position opposite to the base layer with the drift layer sandwiched between the base layer and the collector layer. Each of the trench gate structures includes: a trench penetrating the base layer and reaching the drift layer; a gate insulation film is disposed at a wall surface of the trench; and a gate electrode disposed on the gate insulation film. The emitter region is disposed on a surface layer portion of the base layer and is in contact with the trench.

A semiconductor device includes a bipolar junction transistor having a collector, a base, and an emitter. The collector includes a current collection region, a constriction region laterally adjacent to the current collection region, and a contact region laterally adjacent to the constriction region, located opposite from the current collection region. The current collection region, the constriction region laterally, and the contact region all have the same conductivity type. The base includes a current transmission region contacting the current collection region and a constricting well laterally adjacent to, and contacting, the current transmission region and contacting the constriction region. The current transmission region and the constricting well have an opposite conductivity type than the current collection region, the constriction region laterally, and the contact region.

A semiconductor device, including a semiconductor substrate having a diode portion, wherein the diode portion includes: an anode region which is provided on a front surface of the semiconductor substrate and is of a second conductivity type; a trench portion provided so as to extend in a predetermined extending direction on the front surface of the semiconductor substrate; a trench contact portion provided on the front surface of the semiconductor substrate; and a plug region which is provided at a lower end of the trench contact portion and is of a second conductivity type, and which has a doping concentration higher than that of the anode region, wherein a plurality of plug regions, each of which being the plug region, is provided separately from each other along the extending direction, is provided.

Disclosed is a semiconductor structure that includes an asymmetric lateral bipolar junction transistor (BJT). The BJT includes an emitter, a base, a collector extension and a collector arranged side-by-side (i.e., laterally) across a semiconductor layer. The emitter, collector and collector extension have a first type conductivity with the collector extension having a lower conductivity level than either the emitter or the collector. The base has a second type conductivity that is different from the first type conductivity. With such a lateral configuration, the BJT can be easily integrated with CMOS devices on advanced SOI technology platforms. With such an asymmetric configuration and, particularly, given the inclusion of the collector extension but not an emitter extension, the BJT can achieve a relatively high collector-emitter breakdown voltage (V.sub.br-CEO) without a significant risk of leakage currents at high voltages. Also disclosed are method embodiments for forming such a semiconductor structure.

To improve an on-resistance of a semiconductor device. A plurality of collector regions are formed at a predetermined interval on a bottom surface of a drift layer made of SiC. Next, on the bottom surface of the drift layer, both of the drift layer and a collector region via a silicide layer are connected to a collector electrode.

A three-dimensional carrier stored trench IGBT and a manufacturing method thereof are provided. A P-type buried layer and a split gate electrode with equal potential to an emitter metal is introduced on the basis of the traditional carrier stored trench IGBT, which can effectively eliminate the influence of an N-type carrier stored layer on breakdown characteristics of the device through the charge compensation, and at the same time can reduce the on-state voltage drop and improve the trade-off relationship between the on-state voltage drop Vceon and the turn-off loss Eoff. The split gate electrodes is introduced in the Z-axis direction, so that the gate electrodes are distributed at intervals. Therefore, the channel density is reduced. The turning on of the parasitic PMOS has a potential-clamping effect on the NMOS channel, so that the saturation current can be reduced and a wider short-circuit safe operating area (SCSOA) can be obtained.

Provided is a semiconductor device including a drift region, a base region, two trench portions and a mesa portion, wherein at least one of the two trench portions is a gate trench portion, the mesa portion includes: a first conductivity type emitter region provided to be exposed on an upper surface of the mesa portion; a second conductivity type contact region provided to be exposed on the upper surface of the mesa portion alternately with the emitter region in an extending direction; and a second conductivity type connecting region with a higher doping concentration than the base region, wherein the connecting region is provided to overlap with the emitter region in a top view, is arranged apart from the gate trench portion, is arranged below the upper surface of the mesa portion, and connects two of the contact regions sandwiching the emitter region in the extending direction.