Solder bumps are placed in direct contact with the silicon substrate of an amplifier integrated circuit having a flip chip configuration. A plurality of amplifier transistor arrays generate waste heat that promotes thermal run away of the amplifier if not directed out of the integrated circuit. The waste heat flows through the thermally conductive silicon substrate and out the solder bump to a heat-sinking plane of an interposer connected to the amplifier integrated circuit via the solder bumps.

This specification discloses methods for integrating a SiGe-based HBT (heterojunction bipolar transistor) and a Si-based BJT (bipolar junction transistor) together in a single manufacturing process that does not add a lot of process complexity, and an integrated circuit that can be fabricated utilizing such a streamlined manufacturing process. In some embodiments, such an integrated circuit can enjoy both the benefits of a higher RF (radio frequency) performance for the SiGe HBT and a lower leakage current for the Si-based BJT. In some embodiments, such an integrated circuit can be applied to an ESD (electrostatic discharge) clamp circuit, in order to achieve a lower, or no, yield-loss.

A technique relates to a semiconductor device. A bipolar transistor includes an emitter layer and a base layer, where the emitter layer and the base layer are doped with an impurity, the impurity being a same for the emitter and base layers. The bipolar transistor includes a collector layer.

A semiconductor device has bipolar transistors on a substrate. There is also an insulating film on the substrate, covering the bipolar transistors. On this insulating film is emitter wiring, sticking through openings in the insulating film (first openings) to be electrically coupled to the emitter layer of the bipolar transistors. On the emitter wiring is a protective film. On the protective film is a bump, sticking through an opening in the protective film (second opening) to be electrically coupled to the emitter wiring. In plan view, the second opening is included in the area that is inside the bump and outside the first openings.

A semiconductor device is provided that has a semiconductor substrate, a drift layer of a first conductivity type formed in the semiconductor substrate, a base region of a second conductivity type formed in the semiconductor substrate and above the drift layer, and an accumulation region of the first conductivity type provided between the drift layer and the base region and having an impurity concentration higher than an impurity concentration in the drift layer, wherein the accumulation region has a first accumulation region and a second accumulation region that is formed more shallowly than the first accumulation region is and on a side of a boundary with a region that is different from the accumulation region in a planar view.

Dual-base two-sided bipolar power transistors which use an insulated field plate to separate the emitter/collector diffusions from the nearest base contact diffusion. This provides a surprising improvement in turn-off performance, and in breakdown voltage.

A semiconductor device has bipolar transistors on a substrate. There is also an insulating film on the substrate, covering the bipolar transistors. On this insulating film is emitter wiring, sticking through openings in the insulating film (first openings) to be electrically coupled to the emitter layer of the bipolar transistors. On the emitter wiring is a protective film. On the protective film is a bump, sticking through an opening in the protective film (second opening) to be electrically coupled to the emitter wiring. In plan view, the second opening is included in the area that is inside the bump and outside the first openings.

A technique relates to a semiconductor device. A bipolar transistor includes an emitter layer and a base layer, where the emitter layer and the base layer are doped with an impurity, the impurity being a same for the emitter and base layers. The bipolar transistor includes a collector layer.

A cascode transistor device includes a semiconductor substrate, and a first and a second compound semiconductor transistors. The first compound semiconductor transistor includes a first n-type doping layer, a first p-type doping layer and a second n-type doping layer sequentially disposed on the semiconductor substrate. The second compound semiconductor transistor includes a third n-type doping layer, a second p-type doping layer and a fourth n-type doping layer sequentially disposed on the second n-type doping layer. Each of these doping layers is formed with an exposed metal contact. The exposed metal contact on the second n-type doping layer is electrically connected to the exposed metal contact on the third n-type doping layer.

A method of manufacturing a semiconductor device is provided. The method includes: providing a substrate including a first semiconductive region of a first conductive type and gate structures over the first semiconductive region, wherein a gap between the gate structures exposes a portion of the first semiconductive region; and forming a second semiconductive region of a second conductive type in the gap starting from the exposed portion of the first semiconductive region. The forming of the second semiconductive region includes: growing, in a chamber, an epitaxial silicon-rich layer having a first sidewall adjacent to the gate structures and a first central portion; and, in the chamber, shaping the epitaxial silicon-rich layer to form a second sidewall adjacent to the gate structures and a second central portion, wherein a first height difference between the first sidewall and the first central portion is greater than a second height difference between the second sidewall and the second central portion.