A bipolar transistor includes a common collector region comprising a buried semiconductor layer and an annular well. A well region is surrounded by the annular well and delimited by the buried semiconductor layer. A first base region and a second base region are formed by the well region and separated from each other by a vertical gate structure. A first emitter region is implanted in the first base region, and a second emitter region is implanted in the second base region. A conductor track electrically couples the first emitter region and the second base region to configure the bipolar transistor as a Darlington-type device. Structures of the bipolar transistor may be fabricated in a co-integration with a non-volatile memory cell.

A semiconductor device having a GeSiSn base region combined with an emitter region and a collector region can be used to fabricate a bipolar transistor or a heterojunction bipolar transistor. The GeSiSn base region can be compositionally graded or latticed matched or strained to GaAs. The GeSiSn base region can be wafer bonded to a GaN or SiC collector region.

An oxide layer (109) including an oxide of an electrode (108) material is formed by heating in a portion of an electrode (108) in contact with a surface oxidized layer (107). The oxide layer (109) is placed between the electrode (108) and an i-AlGaN layer (106) in contact with both the i-AlGaN layer (106) and the electrode (108).

The methods of manufacture of GeSiSn heterojunction bipolar transistors, which include light emitting transistors and transistor lasers and photo-transistors and their related structures are described herein. Other embodiments are also disclosed herein.

An integrated circuit includes one or more bipolar transistors, each including a first dielectric layer located over a semiconductor layer having a first conductivity type, the dielectric layer including an opening. A second dielectric layer is located between the first dielectric layer and the semiconductor layer. The second dielectric layer defines a first recess between the first dielectric layer and the semiconductor substrate at a first side of the opening, and a second recess between the first dielectric layer and the semiconductor substrate at a second opposite side of the opening. A first doped region of the semiconductor layer is located under the opening, the first doped region having a different second conductivity type and a first width. A second doped region of the semiconductor layer is also under the opening, the second doped region having the second conductivity type and underlying the first recess and the second recess.

A solar cell is provided. The solar cell includes a p-n junction and a coating. The p-n junction includes upper and lower layers. The coating overlies the upper layer of the p-n junction. The coating includes a transparent conductive layer and a gate dielectric layer, which is interposed between the transparent conductive layer and the upper layer of the p-n junction. The solar cell further includes a front-contact and a back-contact, which are electrically communicative with each other. The front-contact is electrically communicative with the upper layer of the p-n junction through the coating. The back-contact is electrically communicative with the lower layer of the p-n junction. The solar cell can also include a contact via electrically communicative with the back-contact and with the transparent conductive layer.

Provided is a high ruggedness HBT, including a first emitter cap layer and a second emitter cap layer formed between an emitter layer and an ohmic contact layer, or only an emitter cap layer is formed between them. When the first and second emitter cap layers are provided, bandgaps of the first or second emitter cap layer are changed, and the ruggedness of the HBT is improved. When an emitter cap layer is provided, an electron affinity of at least a portion of the emitter cap layer is less than or approximately equal to an electron affinity of the emitter layer, and the ruggedness of the HBT is improved.

The present disclosure relates to semiconductor structures and, more particularly, to a heterojunction bipolar transistor having an emitter base junction with a silicon-oxygen lattice interface and methods of manufacture. The device includes: a collector region buried in a substrate; shallow trench isolation regions, which isolate the collector region buried in the substrate; a base region on the substrate and over the collector region; an emitter region composed of a single crystalline of semiconductor material and located over with the base region; and an oxide interface at a junction of the emitter region and the base region.

The present disclosure relates to semiconductor structures and, more particularly, to a heterojunction bipolar transistor having an emitter base junction with a silicon-oxygen lattice interface and methods of manufacture. The device includes: a collector region buried in a substrate; shallow trench isolation regions, which isolate the collector region buried in the substrate; a base region on the substrate and over the collector region; an emitter region composed of a single crystalline of semiconductor material and located over with the base region; and an oxide interface at a junction of the emitter region and the base region.

Certain embodiments include a cubic boron nitride (c-BN) device. The c-BN device includes a n/n+ Schottky diode and a n/p/n+ bipolar structure. The n/n+ Schottky diode and the /p/n+ bipolar structure are on a single-crystal diamond platform.