Embodiments include a first set of fins having an emitter of a bipolar junction transistor (BJT) disposed over the first set of fins, a second set of fins having a base of the BJT disposed over the second set of fins, and a third set of fins having a collector of the BJT disposed over the third set of fins. A first gate structure is disposed over the first set of fins adjacent to the emitter. A second gate structure is disposed over the second set of fins adjacent to the base. A third gate structure is disposed over the third set of fins adjacent to the collector. The first gate structure, second gate structure, and third gate structure are physically and electrically separated.

A sensor device includes a vertically stacked cascode bipolar junction transistor pair, and a first trench having a first sidewall, wherein a portion of the first sidewall is provided by the first sensing surface, wherein a bipolar junction transistor and a dual-base bipolar junction transistor of the cascode bipolar junction transistor pair are stacked vertically along the first trench.

The present disclosure relates to semiconductor structures and, more particularly, to electrostatic discharge (ESD) devices and methods of manufacture. The structure includes a bipolar transistor device, including a base region, having a base contact region, in a first well of a first conductivity type, a collector region, having a collector contact region, in a second well of a second conductivity type, and an emitter region, having an emitter contact region, in the first well, located between the base contact region and the second well, and a reverse-doped resistance well, of the second conductivity type, located in the first well of the first conductivity type between the base contact region and the emitter contact region structured to decrease turn-on voltage of the bipolar transistor device.

Structures for a bipolar junction transistor and methods of forming a structure for a bipolar junction transistor. The structure includes a collector having a raised portion, an emitter having a raised portion, and a base laterally arranged between the raised portion of the emitter and the raised portion of the collector. The base includes an intrinsic base layer and an extrinsic base layer stacked with the intrinsic base layer. The structure further includes a stress liner positioned to overlap with the raised portion of the collector, the raised portion of the emitter, and the extrinsic base layer.

A bipolar transistor includes a substrate having a first well with a first dopant type; and a split collector region in the substrate, the split collector region including a highly doped central region having the first dopant type, and a lightly doped peripheral region having a second dopant type, opposite the first dopant type, wherein the lightly doped peripheral region surrounds the highly doped central region, a dopant concentration of the lightly doped peripheral region ranges from about 5×10.sup.12 ions/cm.sup.3 to about 5×10.sup.13 ions/cm.sup.3, and the lightly doped peripheral region has a same maximum depth as the highly doped central region.

The present application provides a BJT device structure and a method for making the same, the structure comprising an N+ region located on a P-well; a barrier layer structure located on the N+ region, the barrier layer structure being a frame structure surrounding the periphery of the N+ region, wherein a region in the barrier layer structure is an emitter region, a plurality of mutually spaced STI regions are provided on the N+ region of the emitter region; a base region located at the periphery of the emitter region; and a collector region located at the periphery of the base region. The STI region of the emitter region of the BJT device structure of the present application is a discontinuous structure, which can significantly reduce a recombination current of the emitter region and the base region, thereby effectively increasing the amplification factor of the BJT device.

A method for producing a semiconductor device, the method includes, forming, on a substrate made from a semiconductor substance, at least one bipolar junction (BJ) transistor including a first terminal connected to a first well, the first well formed in the substrate and includes a first dopant having a first dopant concentration. At least one non-BJ transistor is formed on the substrate, the non-BJ transistor includes a second terminal connected to a second well, and the second well formed in the substrate and includes a second dopant having a same polarity as the first dopant. The first dopant concentration of the BJ transistor is higher than the second dopant concentration of the non-BJ transistor.

Structures including III-V compound semiconductor-based devices and silicon-based devices integrated on a semiconductor substrate and methods of forming such structures. The structure includes a substrate having a device layer, a handle substrate, and a buried insulator layer between the handle substrate and the device layer. The structure includes a first semiconductor layer on the device layer in a first device region, and a second semiconductor layer on the device layer in a second device region. The first semiconductor layer contains a III-V compound semiconductor material, and the second semiconductor layer contains silicon. A first device structure includes a gate structure on the first semiconductor layer, and a second device structure includes a doped region in the second semiconductor layer. The doped region and the second semiconductor layer define a p-n junction.

The disclosure provides a lateral bipolar transistor structure with a base layer over a semiconductor buffer, and related methods. A lateral bipolar transistor structure may include an emitter/collector (E/C) layer over an insulator. The E/C layer has a first doping type. A semiconductor buffer is adjacent the insulator. A base layer is on the semiconductor buffer and adjacent the E/C layer, the base layer including a lower surface below the E/C layer and an upper surface above the E/C layer. The base layer has a second doping type opposite the first doping type.

A method of subdividing a semiconductor wafer is described with trenches in order to provide separate, electrically isolated regions that can be used to hold components that operate at different voltages. There is also described a masking and etching process of forming collector and emitter regions of a lateral bipolar transistor, from a layer of polysilicon deposited on a patterned later of silicon dioxide.