A horizontal current bipolar transistor comprises; an n-hill layer on a substrate, forming a first pn-junction with the substrate; a n+ diffusion layer on the substrate, adjacent to the n-hill layer, forming a n+n junction with the n-hill layer; an intrinsic base layer on the n-hill layer and comprising a portion of a sidewall inclined at an acute angle to the substrate plane, forming a second pn-junction with the n-hill layer; an extrinsic base layer on the n-hill layer, forming a third pn-junction with the n-hill layer, and a p.sup.+p junction with the intrinsic base layer; a field limiting region on the n-hill layer, forming a fourth pn-junction with the n-hill layer. The field limiting region is spatially separated from the extrinsic base layer and the n+ diffusion layer. The extrinsic base layer and the field limiting region exhibit substantially equal impurity dopant distribution decay towards the substrate.

A method is presented for forming a monolithically integrated semiconductor device. The method includes forming a first device including first hydrogenated silicon-based contacts formed on a first portion of a semiconductor material of an insulating substrate and forming a second device including second hydrogenated silicon-based contacts formed on a second portion of the semiconductor material of the insulating substrate. Source and drain contacts of the first device are formed before a gate contact of the first device and a gate contact of the second device is formed before the emitter and collector contacts of the second device. The first device can be a heterojunction field effect transistor (HJFET) and the second device can be a (heterojunction bipolar transistor) HBT. The HJFET and the HBT are integrated in a neuronal circuit and create negative differential resistance by forming a lambda diode.

Complementary high-voltage bipolar transistors in silicon-on-insulator (SC) integrated circuits is disclosed. In one disclosed embodiment, a collector region is formed in an epitaxial silicon layer disposed over a buried insulator layer. A base region and an emitter are disposed over the collector region. An n-type region is formed under the buried insulator layer (BOX) by implanting donor impurity through the active region of substrate and BOX into a p-substrate. Later in the process flow this n-type region is connected from the top by doped poly-silicon plug and is biased at Vcc. In this case it will deplete lateral portion of PNP collector region and hence, will increase its BV.

High-performance lateral bipolar junction transistors (BJTs) are provided in which a lightly doped upper intrinsic base region is formed between a lower intrinsic base region and an extrinsic base region. The lightly doped upper intrinsic base region provides two electron paths which contribute to the collector current, I.sub.C. The presence of the lightly doped upper intrinsic base region increases the total I.sub.C and leads to higher current gain, , if there is no increase of the base current, I.sub.B.

A method is presented for forming a monolithically integrated semiconductor device. The method includes forming a first device including first hydrogenated silicon-based contacts formed on a first portion of a semiconductor material of an insulating substrate and forming a second device including second hydrogenated silicon-based contacts formed on a second portion of the semiconductor material of the insulating substrate. Source and drain contacts of the first device are formed before a gate contact of the first device and a gate contact of the second device is formed before the emitter and collector contacts of the second device. The first device can be a heterojunction field effect transistor (HJFET) and the second device can be a (heterojunction bipolar transistor) HBT. The HJFET and the HBT are integrated in a neuronal circuit and create negative differential resistance by forming a lambda diode.

The lateral bipolar junction transistor has a silicon carbide layer, the silicon carbide layer comprises a base region with a first conductivity type, a collector region with a second conductivity type and an emitter region with a second conductivity type. The collector region and the emitter region are within the base region, and the base region, collector region and emitter region are all arranged along an upper surface of the silicon carbide layer.

A bipolar transistor having a semiconductor structure that includes a channel of semiconductor type that is the same as the collector and emitter regions. The channel is significantly shallower than the base region with which it interfaces. The semiconductor structure provides improved current gain. It also enables the device to operate, when on, selectively either with primarily unipolar conduction or with primarily bipolar conduction by control of the voltage across the emitter and collector terminals of the transistor.

Complementary high-voltage bipolar transistors in silicon-on-insulator (SOI) integrated circuits is disclosed. In one disclosed embodiment, a collector region is formed in an epitaxial silicon layer disposed over a buried insulator layer. A base region and an emitter are disposed over the collector region. An n-type region is formed under the buried insulator layer (BOX) by implanting donor impurity through the active region of substrate and BOX into a p-substrate. Later in the process flow this n-type region is connected from the top by doped poly-silicon plug and is biased at Vcc. In this case it will deplete lateral portion of PNP collector region and hence, will increase its BV.

A method for fabricating bipolar junction transistor (BJT) includes the steps of: providing a substrate having an emitter region, a base region, and a collector region; performing a first implantation process to form a first well region in the base region; and performing a second implantation process to form a second well region in the emitter region. Preferably, the first well region and the second well region comprise different concentration.

Integrated circuits including an electrostatic discharge device and methods of forming the integrated circuits are provided herein. In an embodiment, an integrated circuit includes an n-type epitaxy layer, a segmented p-well, a p-type buried layer, and a collector region. The segmented p-well is formed in the n-type epitaxy layer. The segmented p-well defines and laterally surrounds a spacing region of the n-type epitaxy layer. The p-type buried layer is formed in the spacing region. The p-type buried layer laterally extends into the segmented p-well about the spacing region and impedes current flow between an underlying portion of the n-type epitaxy layer in relation to the p-type buried layer and an overlying portion of the n-type epitaxy layer in the spacing region. The collector region of the electrostatic discharge device is formed in the overlying portion of the n-type epitaxy layer in the spacing region.