The present invention concerns a monolithically merged trenched-and-implanted Bipolar Junction Transistor (TI-BJT) with antiparallel diode and a method of manufacturing the same. Trenches are made in a collector, base, emitter stack downto the collector. The base electrode is formed on an implanted base contact region at the bottom surface of the trench. The present invention also provides for products produced by the methods of the present invention and for apparatuses used to perform the methods of the present invention.

A semiconductor device includes a first device including first active regions and first to third structures thereon, and a second device including a second active region, a gate structure intersecting the second active region, and a source/drain region including a lower source/drain region on the second active region having first-type conductivity, an inter-source/drain region insulating layer on the lower source/drain region, and an upper source/drain region on the inter-source/drain region insulating layer and having second-type conductivity. The first structure includes first lower and upper impurity regions. The second structure includes a second lower impurity region having the first-type conductivity, an inter-impurity region insulating layer, and a second upper impurity region having the second-type conductivity. The third structure includes third lower and upper impurity regions having the second-type conductivity, the third upper impurity region having an impurity concentration higher than a that of the third lower impurity region.

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.

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.

Structures for a heterojunction bipolar transistor and methods of forming a structure for a heterojunction bipolar transistor. The structure comprises an emitter, a collector including a first section, a second section, and a third section positioned in a first direction between the first section and the second section, and an intrinsic base disposed in a second direction between the emitter and the third section of the collector. The structure further comprises a stress layer including a section positioned to overlap with the emitter, the intrinsic base, and the collector. The section of the stress layer is surrounded by a perimeter, and the first and second sections of the collector are each positioned adjacent to the perimeter of the stress layer.

Described herein are various amorphous metal thin film transistors. Embodiments of such transistors include an amorphous metal gate electrode and a channel conductor formed on a non-conducting substrate. Further embodiments of such transistors include an amorphous metal source electrode, an amorphous metal drain electrode, and a channel conductor formed on a non-conducting substrate. Methods of forming such transistors are also described.

The present disclosure relates to semiconductor structures and, more particularly, to a bipolar transistor and methods of manufacture. The structure includes: a collector region; an extrinsic base comprising an emitter opening with an angled sidewall; an emitter within the emitter opening; and an intrinsic base between the emitter and the collector.

A semiconductor device includes an emitter, a first base encircling the emitter, a first collector encircling the emitter and the first base, a second base encircling the emitter, the first base and the first collector, and a second collector encircling the second base. The first collector is separated from the emitter by the first base, and the second collector is separated from the emitter, the first base and the first collector by the second base. The emitter, the first base, the first collector, the second base and the second collector form a concentric pattern.

The present disclosure relates to semiconductor structures and, more particularly, to a lateral bipolar transistor and methods of manufacture. The structure includes: an extrinsic base having at least one sidewall with a gradient concentration of semiconductor material; an emitter on a first side of the extrinsic base; and a collector on a second side of the extrinsic base.

A bipolar nanocomposite semiconductor (BNS) material in which electrons and holes are separately transported throughout the BNS volume via an interpenetrating plurality of networks, where some of the networks have one conductivity type and others have the opposite conductivity type. The interpenetrating networks can include one or more multiple nanocrystalline structures, metal and dielectric networks and are intimately connected to enable band-like transport of both electrons and holes throughout the material.