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 includes: a gate trench portion and a dummy trench portion provided extending in a predetermined direction of extension at the upper surface of the semiconductor substrate; a mesa portion sandwiched by the gate trench portion and the dummy trench portion; an emitter region provided between the upper surface of the semiconductor substrate and the drift region and provided at an upper surface of the mesa portion and adjacent to the gate trench portion; and a contact region provided between the upper surface of the semiconductor substrate and the drift region and provided at the upper surface of the mesa portion and adjacent to the dummy trench portion.

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.

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.

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 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.

The present invention relates to an electrical circuit arrangement with an active discharge circuit including at least one electrical switching element, by means of which the circuit arrangement can be discharged in controlled manner. The circuit arrangement includes a RC snubber element with capacitor and resistor for damping voltage or current peaks in the circuit arrangement, wherein the electrical switching element is integrated in the RC snubber element and connected in parallel to the capacitor of the RC snubber. This enables the discharge circuit to be designed in a manner that is economical in terms of space and cost. The discharge circuit uses the heat sink for the RC snubber element and therefore does not need any additional heat dissipation systems.

A method of manufacturing a semiconductor device includes: providing a substrate including a first semiconductive region of a first conductive type and gate structures over the first semiconductive region, where 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 with a first growth rate around a sidewall adjacent to the gate structures that is greater than a second growth rate at a central portion; and, in the chamber, partially removing the epitaxial silicon-rich layer with an etchant with a first etching rate around the sidewall adjacent to the gate structures that is greater than a second etching rate at the central portion.

This disclosure relates to methods of forming bipolar transistors, such as heterojunction bipolar transistors. The methods may include forming a sub-collector over a substrate, forming a first portion of a collector over the sub-collector and doping a second portion of the collector to form a doping spike. The method may further include forming a third portion of the collector over the doping spike and forming a base of the bipolar transistor over the third portion of the collector.

A vertical semiconductor device and method for manufacturing the same is provided. The semiconductor device includes a body with a substrate and an epitaxial layer on the substrate, the layer includes a first region of a first conductivity type, and a second region of a second different conductivity type, the second region is arranged opposite to the substrate with respect to the first region, and when viewed in a first direction from the layer to the substrate, the first region and the second region each extend across an entire area of the body. The device further includes a trench arranged in the body, extending through the second region and at least partially into the first region, thereby dividing the second region into an inner and an outer portion that are mutually electrically isolated, and a first conductive contact on the second region to enable electrically accessing the inner portion.