Bipolar junction transistor structures and methods for making the same are provide. The method includes: providing a substrate with an insulator layer and a device layer over the insulator layer, forming an intrinsic base from the device layer, forming emitter and collector regions from the device layer, and after forming i) the intrinsic base and ii) the emitter and collector regions, depositing a single crystalline extrinsic base over the intrinsic base.

An integrated circuit includes a transistor that has an collector region, a base region laterally surrounded by the collector region, and an emitter region laterally surrounded by the base region. A silicide layer on the emitter region is laterally spaced apart from the base region by an unsilicided ring. The emitter region is laterally spaced apart from a base contact region that may be covered by a dielectric layer such as a gate oxide layer.

A lateral transistor tile is formed with first and second collector regions that longitudinally span first and second sides of the transistor tile; and a base region and an emitter region that are between the first and second collector regions and are both centered on a longitudinal midline of the transistor tile. A base-collector current, a collector-emitter current, and a base-emitter current flow horizontally; and the direction of the base-emitter current is perpendicular to the direction of the base-collector current and the collector-emitter current. Lateral BJT transistors having a variety of layouts are formed from a plurality of the tiles and share common components thereof.

A structure and method of forming a lateral bipolar junction transistor (LBJT) that includes: a first base layer, a second base layer over the first base layer, and an emitter region and collector region present on opposing sides of the first base layer, where the first base layer has a wider-band gap than the second base layer, and where the first base layer includes a III-V semiconductor material.

Structures for a heterojunction bipolar transistor and methods of forming a structure for a heterojunction bipolar transistor. A base layer is positioned in a cavity in a semiconductor layer, a first terminal is coupled to the base layer, and a second terminal is coupled to a portion of the semiconductor layer. The second terminal is laterally spaced from the first terminal, and the portion of the semiconductor layer is laterally positioned between the second terminal and the base layer.

A MOSFET and an electrostatic discharge (ESD) protection device on a common chip includes a MOSFET with a source, a gate, and a drain, and an ESD protection device configured to implement a diode function that is biased to prevent current from flowing through the common chip from the source to the drain.

Embodiments of the disclosure provide a lateral bipolar transistor structure with a superlattice layer and methods to form the same. The bipolar transistor structure may have a semiconductor layer of a first single crystal semiconductor material over an insulator layer. The semiconductor layer includes an intrinsic base region having a first doping type. An emitter/collector (E/C) region may be adjacent the intrinsic base region and may have a second doping type opposite the first doping type. A superlattice layer is on the E/C region of the semiconductor layer. A raised E/C terminal, including a single crystal semiconductor material, is on the superlattice layer. The superlattice layer separates the E/C region from the raised E/C terminal.

A transistor includes a substrate of a first conductivity type. An epitaxial layer of the first conductivity type is formed at a top surface of the substrate. A first region of the first conductivity type is formed as a well in the epitaxial layer. A second region of a second conductivity type is formed as a well in the epitaxial layer adjacent to the first region and the second conductivity type is opposite of the first conductivity type. A third region of the second conductivity type is formed in the first region and a portion of the first region forms a channel region between the third region and the second region. An emitter region of the first conductivity type is formed in the second region. A gate dielectric is formed over the channel region, and a gate electrode is formed on gate dielectric with the gate electrode overlapping at least a portion of second region and the third region.

The semiconductor device has the main surface, the semiconductor substrate having the first impurity region formed on the main surface, the first electrode formed on the main surface having the first impurity region, the insulating film formed on the main surface such that surround the first electrode, the second electrode formed on the insulating film such that spaced apart from the first electrode and annularly surround the first electrode, and the semi-insulating film. The first electrode has the outer peripheral edge portion. The semi-insulating film is continuously formed from on the outer peripheral edge portion to on the second electrode. The outer peripheral edge portion includes the first corner portion. The second electrode has the second corner portion facing the first corner portion. The semi-insulating film on the insulating film is removed between the first corner and the second corner portion.

A method of forming a lateral bipolar junction transistor (LBJT) that includes providing a germanium containing layer on a crystalline oxide layer, and patterning the germanium containing layer stopping on the crystalline oxide layer to form a base region. The method may further include forming emitter and collector extension regions on opposing sides of the base region using ion implantation, and epitaxially forming an emitter region and collector region on the crystalline oxide layer into contact with the emitter and collector extension regions. The crystalline oxide layer provides a seed layer for the epitaxial formation of the emitter and collector regions.