After forming an epitaxial germanium layer over a germanium-on-insulator substrate including an insulator layer and a doped germanium layer overlying the insulator layer, the doped germanium layer is selectively removed and a passivation layer is formed within a space between the epitaxial germanium layer and the insulator layer that is formed by removal of the doped germanium layer. A lateral bipolar transistor is subsequently formed in the epitaxial germanium layer.

The method of manufacturing an integrated circuit includes obtaining a silicon carbide substrate of a first conductivity type having an epitaxial layer of a second conductivity type thereon. A dopant is implanted in the epitaxial layer to form a first region of the first conductivity type that extends the full depth of the epitaxial layer. A first transistor is formed in the first region and a second transistor is formed in the epitaxial layer.

In some embodiments, a BJT structure includes a base region, an emitter region formed in the base region and including an emitter doping region, a collector region including a collector doping region, an insulating structure and a field plate. The base region forms a junction with the collector region between the emitter and collector doping regions. The field plate is formed over an insulating structure over the junction. A first distance between the corresponding emitter and collector doping regions to the junction is shorter than a second distance in another BJT structure without the field plate corresponding to the first distance. The first distance causes a breakdown of the junction corresponding to a first breakdown voltage value between the emitter and collector doping regions being substantially the same or greater than a second breakdown voltage value of the other BJT structure corresponding to the first breakdown voltage value.

The disclosure provides a bipolar transistor structure with multiple bases, and related methods. A bipolar transistor structure includes a first emitter/collector (E/C) material above an insulator. The first E/C material has first sidewall and a second sidewall over the insulator. A first base is above the insulator adjacent the first sidewall of the first E/C material. A second base is above the insulator adjacent the second sidewall of the first E/C material. A second E/C material is above the insulator and adjacent the first base. A width of the first base between the first E/C material and the second E/C material is less than a width of the first E/C material, and the first base protrudes horizontally outward from an end of the first E/C material and an end of the second E/C material.

One illustrative device disclosed herein includes a semiconductor substrate and a bipolar junction transistor (BJT) device that comprises a collector region, a base region and an emitter region. In this example, the device also includes a field effect transistor and at least one base conductive contact structure that conductively and physically contacts the base region.

A bipolar junction transistor layout structure includes a first emitter including a pair of first sides and a pair of second sides, a pair of collectors disposed at the first sides of the first emitter, and a pair of bases disposed at the second sides of the first emitter. The first sides are perpendicular to the second sides. The first emitter is disposed in between the pair of collectors and in between the pair of bases.

In one example, a sensor includes a heterojunction bipolar transistor and component sensing surface coupled to the heterojunction bipolar transistor via an extended base component. In another example, a biosensor for detecting a target analyte includes a heterojunction bipolar transistor and a sensing surface. The heterojunction bipolar transistor includes a semiconductor emitter including an emitter electrode for connecting to an emitter voltage, a semiconductor collector including a collector electrode for connecting to a collector voltage, and a semiconductor base positioned between the semiconductor emitter and the semiconductor collector. The sensing surface is coupled to the semiconductor base of the heterojunction bipolar transistor via an extended base component and includes a conducting film and a reference electrode.

Semiconductor structure including germanium-on-insulator lateral bipolar junction transistors and methods of fabricating the same generally include formation of a silicon passivation layer at an interface between the insulator layer and a germanium layer.

A lateral bipolar junction transistor (LBJT) device that includes an intrinsic III-V semiconductor material having a first band gap; and a base region present on the intrinsic III-V semiconductor material. The base region is composed of an III-V semiconductor material having a second band gap that is less than the first band gap. Emitter and collector regions present on opposing sides of the base region. The emitter and collector regions are composed of epitaxial III-V semiconductor material that is present on the intrinsic III-V semiconductor material.

An ESD protection device is fabricated in a semiconductor substrate that includes a semiconductor layer having a first conductivity type. A first well implantation procedure implants dopant of a second conductivity type in the semiconductor layer to form inner and outer sinker regions. The inner sinker region is configured to establish a common collector region of first and second bipolar transistor devices. A second well implantation procedure implants dopant of the first conductivity type in the semiconductor layer to form respective base regions of the first and second bipolar transistor devices. Conduction of the first bipolar transistor device is triggered by breakdown between the inner sinker region and the base region of the first bipolar transistor device. Conduction of the second bipolar transistor device is triggered by breakdown between the outer sinker region and the base region of the second bipolar transistor device.