Abstract: An embodiment of a semiconductor device may include a semiconductor substrate, a first semiconductor region comprising a first material with a first polarity formed within the semiconductor substrate and a second semiconductor region comprising the first material with a second polarity formed within the semiconductor substrate and coupled to the first semiconductor region. In an embodiment, a semiconductor device may also include a first electrode coupled to the first semiconductor region, a second electrode coupled to the second semiconductor region, and a depletion region formed between the first semiconductor region and the second semiconductor region. The depletion region may include a mixed crystal region that includes a mixed crystal alloy of the first material and a second material, wherein the mixed crystal region has a lower bandgap energy than a bandgap energy of the first material.

Abstract: A semiconductor switch device and a method of making the same. The device includes a semiconductor substrate having a major surface. The device also includes a first semiconductor region located in the substrate beneath the major surface. The device includes an elongate gate located on the major surface. The device also includes a source region and a drain region located in the first semiconductor region adjacent respective first and second elongate edges of the gate. The device also includes electrical contacts for the source and drain regions. The contacts include at least two contacts located on either the source region or the drain region, which are spaced apart along a direction substantially parallel the elongate edges of the gate. The device further includes an isolation region located between the at least two contacts. The isolation region extends through the source/drain region from the major surface to the first semiconductor region.

Abstract: A semiconductor switch device for switching an RF signal and a method of making the same. The device includes a first semiconductor region having a first conductivity type. The device also includes a source region and a drain region located in the first semiconductor region. The source region and the drain region have a second conductivity type. The second conductivity type is different to the first conductivity type. The device further includes a gate separating the source region from the drain region. The device also includes at least one sinker region having the second conductivity type. Each sinker region is connectable to an external potential for drawing minority carriers away from the source and drain regions to reduce a leakage current at junctions between the source and drain regions and the first semiconductor region.

Abstract: A semiconductor switch device and a method of making the same. The device includes a semiconductor substrate having a major surface. The device also includes a first semiconductor region located in the substrate beneath the major surface. The device includes an elongate gate located on the major surface. The device also includes a source region and a drain region located in the first semiconductor region adjacent respective first and second elongate edges of the gate. The device also includes electrical contacts for the source and drain regions. The contacts include at least two contacts located on either the source region or the drain region, which are spaced apart along a direction substantially parallel the elongate edges of the gate. The device further includes an isolation region located between the at least two contacts. The isolation region extends through the source/drain region from the major surface to the first semiconductor region.

Abstract: Disclosed is a transistor having a first region of a first conductivity type for injecting charge carriers into the transistor and a laterally extended second region of the first conductivity type having a portion including a contact terminal for draining said charge carriers from the transistor, wherein the first region is separated from the second region by an intermediate region of a second conductivity type defining a first p-n junction with the first region and a second p-n junction with the second region, wherein the laterally extended region separates the portion from the second p-n junction, and wherein the transistor further comprises a substrate having a doped region of the second conductivity type, said doped region being in contact with and extending along the laterally extended second region and a further contact terminal connected to the doped region for draining minority charge carriers from the laterally extended second region.

Abstract: A semiconductor switch device for switching an RF signal and a method of making the same. The device includes a first semiconductor region having a first conductivity type. The device also includes a source region and a drain region located in the first semiconductor region. The source region and the drain region have a second conductivity type. The second conductivity type is different to the first conductivity type. The device further includes a gate separating the source region from the drain region. The device also includes at least one sinker region having the second conductivity type. Each sinker region is connectable to an external potential for drawing minority carriers away from the source and drain regions to reduce a leakage current at junctions between the source and drain regions and the first semiconductor region.

Abstract: A circuit, comprising a semiconductor device with one or more field gate terminals for controlling the electric field in a drift region of the semiconductor device; and a feedback circuit configured to dynamically control a bias voltage or voltages applied to the field gate terminal or terminals, with different control voltages used for different semiconductor device characteristics in real-time in response to a time-varying signal at a further node in the circuit.

Abstract: Disclosed is a method of manufacturing a vertical bipolar transistor in a CMOS process, comprising implanting an impurity of a first type into a the substrate (100) to form a buried region (150, 260) therein; forming a halo implant (134) using an impurity of a second type and a shallow implant (132) using an impurity of the first type, said halo implant enveloping the shallow implant in the substrate and being located over said buried region (150, 250); forming, adjacent to the halo implant (134), a further implant (136) using an impurity of the second type for providing a conductive connection to the halo implant; and providing respective connections (170, 160, 270) to the further implant (136), the shallow implant (132) and the buried region (150, 260) allowing the shallow implant, halo implant and buried region to be respectively operable as emitter, base and collector of the vertical bipolar transistor.

Abstract: A semiconductor device and a method of making the same. The device includes a semiconductor substrate. The device also includes a bipolar transistor on the semiconductor substrate. The bipolar transistor includes an emitter. The bipolar transistor also includes a base located above the emitter. The bipolar transistor further includes a laterally extending collector located above the base. The collector includes a portion that extends past an edge of the base.

Abstract: Disclosed is a transistor having a first region of a first conductivity type for injecting charge carriers into the transistor and a laterally extended second region) of the first conductivity type having a portion including a contact terminal for draining said charge carriers from the transistor, wherein the first region is separated from the second region by an intermediate region of a second conductivity type defining a first p-n junction with the first region and a second p-n junction with the second region, wherein the laterally extended region separates the portion from the second p-n junction, and wherein the transistor further comprises a substrate having a doped region of the second conductivity type, said doped region being in contact with and extending along the laterally extended second region and a further contact terminal connected to the doped region for draining minority charge carriers from the laterally extended second region.

Abstract: A circuit, comprising a semiconductor device with one or more field gate terminals for controlling the electric field in a drift region of the semiconductor device; and a feedback circuit configured to dynamically control a bias voltage or voltages applied to the field gate terminal or terminals, with different control voltages used for different semiconductor device characteristics in real-time in response to a time-varying signal at a further node in the circuit.

Abstract: A semiconductor device and a method of making the same. The device includes a semiconductor substrate. The device also includes a bipolar transistor on the semiconductor substrate. The bipolar transistor includes an emitter. The bipolar transistor also includes a base located above the emitter. The bipolar transistor further includes a laterally extending collector located above the base. The collector includes a portion that extends past an edge of the base.

Abstract: Disclosed is a method of manufacturing a vertical bipolar transistor in a CMOS process, comprising implanting an impurity of a first type into a the substrate (100) to form a buried region (150, 260) therein; forming a halo implant (134) using an impurity of a second type and a shallow implant (132) using an impurity of the first type, said halo implant enveloping the shallow implant in the substrate and being located over said buried region (150, 250); forming, adjacent to the halo implant (134), a further implant (136) using an impurity of the second type for providing a conductive connection to the halo implant; and providing respective connections (170, 160, 270) to the further implant (136), the shallow implant (132) and the buried region (150, 260) allowing the shallow implant, halo implant and buried region to be respectively operable as emitter, base and collector of the vertical bipolar transistor.

Abstract: The invention relates to a semiconductor device with a substrate (11) and a semiconductor body (12) with a heterojunction bipolar, in particular npn, transistor with an emitter region (1), a base region (2) and a collector region (3), which are provided with, respectively, a first, a second and a third connection conductor (4, 5, 6), and wherein the bandgap of the base region (2) is smaller than that of the collector region (3) or of the emitter region (1), for example by the use of a silicon-germanium mixed crystal instead of pure silicon in the base region (2). Such a device is characterized by a very high speed, but its transistor shows a relatively low BVeeo. In a device (10) according to the invention the doping flux of the emitter region (1) is locally reduced by a further semiconductor region (20) of the second conductivity type which is embedded in the emitter region (1).

Abstract: The invention relates to a semiconductor device (10) with a semiconductor body (12) comprising a bipolar transistor with an emitter region (1), a base region (2) and a collector region (3) of, respectively, a first conductivity type, a second conductivity type, opposite to the first conductivity type, and the first conductivity type, wherein, viewed in projection, the emitter region (1) is positioned above or below the base region (2), and the collector region (3) laterally borders the base region (2). According to the invention, the base region (2) comprises a highly doped subregion (2A) the doping concentration of which has a delta-shaped profile in the thickness direction, and said highly doped sub-region (2A) extends laterally as far as the collector region (3). Such a lateral bipolar transistor has excellent high-frequency properties and a relatively high breakdown voltage between the base and collector regions (2, 3), implying that the device is suitable for high power applications.

Abstract: The invention relates to a semiconductor device (10) comprising a substrate (11) and a semiconductor body (1) of silicon having a semiconductor layer structure comprising, in succession, a first and a second semiconductor layer (2, 3), and having a surface region of a first conductivity type which is provided with a field effect transistor (M) with a channel of a second conductivity type, opposite to the first conductivity type, wherein the surface region is provided with source and drain regions (4A, 4B) of the second conductivity type for the field effect transistor (M) and with—interposed between said source and drain regions—a channel region (3A) with a lower doping concentration which forms part of the second semiconductor layer (3) and with a buried first-conductivity-type semiconductor region (2A), buried below the channel region (3A), with a doping concentration that is much higher than that of the channel region (3A) and which forms part of the first semiconductor layer (2).

Abstract: The invention relates to a semiconductor device (10) with a semiconductor body (12) comprising a bipolar transistor with an emitter region (1), a base region (2) and a collector region (3) of, respectively, a first conductivity type, a second conductivity type, opposite to the first conductivity type, and the first conductivity type, wherein, viewed in projection, the emitter region (1) is positioned above or below the base region (2), and the collector region (3) laterally borders the base region (2). According to the invention, the base region (2) comprises a highly doped subregion (2A) the doping concentration of which has a delta-shaped profile in the thickness direction, and said highly doped sub-region (2A) extends laterally as far as the collector region (3). Such a lateral bipolar transistor has excellent high-frequency properties and a relatively high breakdown voltage between the base and collector regions (2, 3), implying that the device is suitable for high power applications.

Abstract: The invention relates to a radiation-emitting semiconductor device (10) with a semiconductor body (1) and a substrate (2), wherein the semiconductor body (1) comprises a vertical bipolar transistor with an emitter region (3), a base region (4) and a collector region (5), which regions are each provided with a connection region (6, 7, 8), and the border between the base region (4) and the collector region (5) forms a pn-junction and, in operation, at a reverse bias of the pn-junction or at a sufficiently large collector current, avalanche multiplication of charge carriers occurs whereby radiation is generated in the collector region (5). According to the invention, the collector region (5) has a thickness through which transmission of the generated radiation occurs, and the collector region (5) borders on a free surface of the semiconductor body (1).

Abstract: The invention relates to a semiconductor device with a heterojunction bipolar, in particular npn, transistor with an emitter region (1), a base region (2), and a collector region (3), which are provided with respectively a first, a second, and a third connection conductor (4, 5, 6), while the bandgap of the base region (2) is lower than that of the collector region (3) or of the emitter region (1), for example owing to the use of a silicon-germanium alloy instead of pure silicon. Such a device is very fast, but its transistor shows a relatively low BVceo. In a device according to the invention, the emitter region (1) or the base region (2) comprises a sub-region (1B, 2B) with a reduced doping concentration, which sub-region (1B, 2B) is provided with a further connection conductor (4B, 5B) which forms a Schottky junction with the sub-region (1B, 2B). Such a device results in a transistor with a particularly high cut-off frequency fT but with no or hardly any reduction of the BVceo.

Abstract: The bipolar transistor comprises a collector region (1) of a semiconductor material having a first doping type, a base region (2) of a semiconductor material having a second doping type, and an emitter region (3) having the first doping type. A junction is present between the emitter region (3) and the base region (2), and, viewed from the junction (4), a depletion region (5) extends into the emitter region (3). The emitter region (3) comprises a layer (6) of a first semiconductor material and a layer (7) of a second semiconductor material. The first semiconductor material has a higher intrinsic carrier concentration than the second semiconductor material. The layer (7) of said second semiconductor material is positioned outside the depletion region (5). The second semiconductor material has such a doping concentration that Auger recombination occurs. The invention also relates to a semiconductor device comprising such a bipolar transistor.