A semiconductor device including a Horizontal Current Bipolar Transistor (HCBT) and methods of manufacture. The device has a semiconductor substrate of a first conductivity type defining a wafer plane parallel to the semiconductor substrate and has a base region and a collector region forming a first metallurgical junction. The device also has an emitter region forming a second metallurgical junction with the base region. A flat portion of the first metallurgical junction and a flat portion of the second metallurgical junction are substantially parallel to each other and close an acute angle with the wafer plane. At least a portion of the base region comprises silicon-germanium alloy or silicon-germanium-carbon alloy.

Structures for a bipolar junction transistor and methods of forming a structure for a bipolar junction transistor. The structure includes a collector having a raised portion, an emitter having a raised portion, and a base laterally arranged between the raised portion of the emitter and the raised portion of the collector. The base includes an intrinsic base layer and an extrinsic base layer stacked with the intrinsic base layer. The structure further includes a stress liner positioned to overlap with the raised portion of the collector, the raised portion of the emitter, and the extrinsic base layer.

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.

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.

Structures including III-V compound semiconductor-based devices and silicon-based devices integrated on a semiconductor substrate and methods of forming such structures. The structure includes a substrate having a device layer, a handle substrate, and a buried insulator layer between the handle substrate and the device layer. The structure includes a first semiconductor layer on the device layer in a first device region, and a second semiconductor layer on the device layer in a second device region. The first semiconductor layer contains a III-V compound semiconductor material, and the second semiconductor layer contains silicon. A first device structure includes a gate structure on the first semiconductor layer, and a second device structure includes a doped region in the second semiconductor layer. The doped region and the second semiconductor layer define a p-n junction.

The disclosure provides a lateral bipolar transistor structure with a base layer over a semiconductor buffer, and related methods. A lateral bipolar transistor structure may include an emitter/collector (E/C) layer over an insulator. The E/C layer has a first doping type. A semiconductor buffer is adjacent the insulator. A base layer is on the semiconductor buffer and adjacent the E/C layer, the base layer including a lower surface below the E/C layer and an upper surface above the E/C layer. The base layer has a second doping type opposite the first doping type.

Disclosed semiconductor structure embodiments include a bipolar junction device configured to have a high holding voltage. The device includes base, collector and emitter terminals. The high holding voltage is achieved because of a uniquely configured emitter terminal. Specifically, the device includes a base well region, which has a first-type conductivity. The emitter terminal includes, adjacent to the base well region (e.g., within and/or on the base well region), an emitter contact region, which has a second-type conductivity, and an ancillary emitter region, which abuts the emitter contact region and which has the first-type conductivity at a higher conductivity level than the base well region. Embodiments vary with regard to the shapes of the emitter contact region and ancillary emitter region. Embodiments also vary with regard to the structures used to isolate the collector terminal from the emitter terminal and with regard to the areas covered by silicide layers.

A bipolar transistor is capable of reducing variations in electrical characteristics. A bipolar transistor 100 includes: a collector region 150 which is a predetermined region in a P-type semiconductor substrate 110; a base region 140 which is formed within the collector region 150 and is an N-type well region; a polysilicon 130 formed on the base region 140 via an insulating film 131 and having an outer periphery, as viewed in a plan view, in a rectangular ring shape; and a P-type emitter region 120 surrounded by the polysilicon 130 and formed within the base region 140. The polysilicon 130 includes an extension portion 130a extending inside a contact region 141 of the base region 140 and electrically connected to the base region 140.

Disclosed is a semiconductor structure including a device, such as a lateral heterojunction bipolar transistor (HBT), made up of a combination of at least three different semiconductor materials with different bandgap sizes for improved performance. In the device, a base layer of the base region can be positioned laterally between a collector layer of a collector region and an emitter layer of an emitter region and can be physically separated therefrom by buffer layers. The base layer can be made of a narrow bandgap semiconductor material, the collector layer and, optionally, the emitter layer can be made of a wide bandgap semiconductor material, and the buffer layers can be made of a semiconductor material with a bandgap between that of the narrow bandgap semiconductor material and the wide bandgap semiconductor material. Also disclosed herein is a method of forming the structure.

A structure for a lateral bipolar junction transistor is provided. The structure comprising an emitter including a first concentration of a first dopant. A collector including a second concentration of the first dopant, the first concentration of the first dopant may be different from the second concentration of the first dopant. An intrinsic base may be laterally arranged between the emitter and the collector, and an extrinsic base region may be above the intrinsic base. An emitter extension may be arranged adjacent to the emitter, whereby the emitter extension laterally extends under a portion of the extrinsic base region. A halo region may be arranged adjacent to the emitter extension, whereby the halo region laterally extends under another portion of the extrinsic base region.