A semiconductor device includes a silicon substrate, a first layer, a second layer, a barrier metal, and a gate pad. The first layer is formed of an oxide film provided on an upper surface of the silicon substrate. The second layer is a layer at least selectively having a projecting and recessed part on an upper surface of the first layer, the projecting and recessed part having a projection and recess deeper than a projection and recess occurring when the layer is formed in a planar shape. The barrier metal is formed on an upper surface of the second layer according to a shape of the projecting and recessed part. The gate pad is in close contact with the silicon substrate via the barrier metal.

A semiconductor device is described herein. The semiconductor device includes a substrate and a collector region in the substrate. The semiconductor device also includes a plurality of emitter regions in the substrate, each of the plurality emitter regions separate from each other, wherein the plurality of emitter regions is disposed in an area bounded by the collector region.

Structures for a heterojunction bipolar transistor and methods of forming a structure for a heterojunction bipolar transistor. The structure comprises an intrinsic base including a first semiconductor layer, a collector including a second semiconductor layer, and an emitter including a third semiconductor layer. The first semiconductor layer, which comprises silicon-germanium, includes a first portion and a second portion adjacent to the first portion. The second semiconductor layer includes a portion on the first portion of the first semiconductor layer, and the third semiconductor layer includes a portion on the second portion of the first semiconductor layer. The structure further comprises a dielectric spacer laterally between the portion of the second semiconductor layer and the portion of the third semiconductor layer.

Various particular embodiments include an integrated circuit (IC) structure having: a stack region; and a silicon substrate underlying and contacting the stack region, the silicon substrate including: a silicon region including a doped subcollector region; a set of isolation regions overlying the silicon region; a base region between the set of isolation regions and below the stack region, the base region including an intrinsic base contacting the stack region, an extrinsic base contacting the intrinsic base and the stack region, and an amorphized extrinsic base contact region contacting the extrinsic base; a collector region between the set of isolation regions; an undercut collector-base region between the set of isolation regions and below the base region; and a collector contact region contacting the collector region under the intrinsic base and the collector-base region via the doped subcollector region.

Provided is a method for manufacturing a semiconductor device that improves the reliability of the semiconductor device. An opening is formed in an insulating film formed over a semiconductor substrate. At that time, a mask layer for formation of the opening is formed over the insulating film. The insulating film is dry etched and then wet etched. The dry etching step is finished before the semiconductor substrate is exposed at the bottom of the opening, and the wet etching step is finished after the semiconductor substrate is exposed at the bottom of the opening.

A method comprises arranging a stack, on a semiconductor substrate, comprising a sacrificial layer and an insulating layer. The insulator layer is at least partially arranged between the semiconductor substrate and the sacrificial layer. A recess is formed within the stack. The recess extends through the stack to the semiconductor substrate so that the recess at least partially overlaps with a surface of the collector region of the semiconductor substrate. The collector region extends from a main surface of the semiconductor substrate into the substrate material. The method further comprises generating a base structure at the collector region and in the recess. The base structure contacts and covers the collector region within the recess of the sacrificial layer. The method further comprises generating an emitter structure at the base structure. The emitter structure contacts and at least partially covers the base structure within the recess of the sacrificial layer.

A bipolar junction transistor includes an emitter, a base contact, a collector and a shallow trench isolation. The base contact has two base fingers that form a corner to receive the emitter. The collector has two collector fingers extending along the base fingers of the base contact. The shallow trench isolation is disposed in between the emitter and the base contact and in between the base contact and the collector.

Provided is a method for manufacturing a semiconductor device that improves the reliability of the semiconductor device. An opening is formed in an insulating film formed over a semiconductor substrate. At that time, a mask layer for formation of the opening is formed over the insulating film. The insulating film is dry etched and then wet etched. The dry etching step is finished before the semiconductor substrate is exposed at the bottom of the opening, and the wet etching step is finished after the semiconductor substrate is exposed at the bottom of the opening.

A symmetrically-bidirectional bipolar transistor circuit where the two base contact regions are clamped, through a low-voltage diode and a resistive element, to avoid bringing either emitter junction to forward bias. This avoids bipolar gain in the off state, and thereby avoids reduction of the withstand voltage due to bipolar gain.

A bipolar junction transistor includes an intrinsic base formed on a substrate. The intrinsic base includes a superlattice stack including a plurality of alternating layers of semiconductor material. A collector and emitter are formed adjacent to the intrinsic base on opposite sides of the base. An extrinsic base structure is formed on the intrinsic base.