Transistor-based sensors and fabrication methods for a transistor-based sensor. A semiconductor layer is arranged over a substrate, and an interconnect structure is arranged over the semiconductor layer and the substrate. The semiconductor layer includes first sections composed of a semiconductor material, second sections composed of the semiconductor material, and cavities. The first sections have an alternating arrangement with the second sections in a lateral direction. The semiconductor material of the first sections is polycrystalline, and the semiconductor material of the second sections is single-crystal. First and second openings each extend in a vertical direction through the metallization levels of the interconnect structure to the semiconductor layer or through the substrate to the semiconductor layer. The first opening defines a first fluid inlet coupled to the cavities, and the second opening defines a first fluid outlet coupled to the cavities.

A semiconductor device includes a collector layer, a base layer, and an emitter layer that are disposed above a substrate. An emitter mesa layer is disposed on a partial region of the emitter layer. In a plan view, the base electrode is disposed in or on a region which does not overlap the emitter mesa layer. The base electrode allows base current to flow to the base layer. In the plan view, a first edge forming part of edges of the emitter mesa layer extends in a first direction, and a second edge forming part of edges of the base electrode faces the first edge. A gap between the first edge and the second edge in a terminal portion located in an end portion of the emitter mesa layer in the first direction is wider than a gap in an intermediate portion of the emitter mesa layer.

Power amplifiers in radio frequency circuits are typically implemented as heterojunction bipolar transistors. In applications such as in 5G systems, the circuits are expected to operate at very high speeds, e.g., up to 100 GHz. Also, a certain amount of output power should be maintained for stable operation. To achieve both high power and high speed, it is proposed to incorporate field plates in the heterojunction bipolar transistors to reduce electric field in the collector. This allows the breakdown voltage of the transistor to be high, which aids in power output. At the same time, the collector can be relatively thin, which aids in operation speed.

A semiconductor device includes a plurality of unit transistors that are arranged on a surface of a substrate in a first direction. Input capacitive elements are arranged so as to correspond to the unit transistors. An emitter common wiring line is connected to emitter layers of the unit transistors. A via-hole extending from the emitter common wiring line to a back surface of the substrate is disposed at a position overlapping the emitter common wiring line. A collector common wiring line is connected to collector layers of the unit transistors. The input capacitive elements, the emitter common wiring line, the unit transistors, and the collector common wiring line are arranged in this order in a second direction. Base wiring lines that connect the input capacitive elements to base layers of the corresponding unit transistors intersect the emitter common wiring line without physical contact.

Power amplifiers in radio frequency circuits are typically implemented as heterojunction bipolar transistors. In applications such as in 5G systems, the circuits are expected to operate at very high speeds, e.g., up to 100 GHz. Also, a certain amount of output power should be maintained for stable operation. To achieve both high power and high speed, it is proposed to incorporate field plates in the heterojunction bipolar transistors to reduce electric field in the collector. This allows the breakdown voltage of the transistor to be high, which aids in power output. At the same time, the collector can be relatively thin, which aids in operation speed.

A bipolar transistor includes a collector layer, a base layer, and an emitter layer that are formed in this order on a compound semiconductor substrate. The emitter layer is disposed inside an edge of the base layer in plan view. A base electrode is disposed on partial regions of the emitter layer and the base layer so as to extend from an inside of the emitter layer to an outside of the base layer in plan view. An insulating film is disposed between the base electrode and a portion of the base layer, with the portion not overlapping the emitter layer. An alloy layer extends from the base electrode through the emitter layer in a thickness direction and reaches the base layer. The alloy layer contains at least one element constituting the base electrode and elements constituting the emitter layer and the base layer.

A bipolar junction transistor includes: an emitter region; a base region; and a collector region, wherein each of the emitter region, the base region, and the collector region comprises fin-shaped structures. Preferably, the emitter region, the base region, and the collector region are disposed along a first direction and the fin-shaped structures are disposed along a second direction, in which the first direction is orthogonal to the second direction.

A semiconductor apparatus includes a substrate, plural transistor groups disposed on the substrate, an insulating film, and a metal member. Each of the plural transistor groups includes plural unit transistors arranged in a first direction within a plane of a top surface of the substrate. The plural transistor groups are arranged in a second direction perpendicular to the first direction. The insulating film covers the plural unit transistors and includes at least one cavity. The metal member is disposed on the insulating film and is electrically connected to the plural unit transistors via the at least one cavity. A heat transfer path is formed by a metal in a region from each of the plural unit transistors to a top surface of the metal member. Thermal resistance values of the heat transfer paths are different from each other among the plural unit transistors.

A method for forming a heterojunction bipolar transistor is provided. The method includes (a) forming a doped region in a group IV semiconductor layer of a substrate; (b) forming an epitaxially grown III-V semiconductor body on a surface portion of the doped region, the body extending from the surface portion and protruding vertically above the doped region, wherein the doped region and the body forms a first sub-collector part and a second sub-collector part, respectively; and (c) forming an epitaxially grown III-V semiconductor layer stack on the body, the layer stack comprising a collector, a base and an emitter. There is further provided a heterojunction bipolar transistor device.

An emitter mesa and a base electrode are arranged on a base mesa on a substrate. A base wiring line on the base electrode is connected to the base electrode via base openings. The emitter mesa includes a plurality of emitter fingers having a planar shape that is long in one direction. The emitter fingers include first and second emitter fingers. The base openings are arranged so as to be spaced apart in a longitudinal direction from first end portions of the first emitter fingers and are not arranged in a region obtained by extending the second emitter finger in the longitudinal direction. An end portion of the second emitter finger that is near the base openings protrudes in the longitudinal direction beyond the end portions of the first emitter fingers that are near the base openings.