A semiconductor device includes a semiconductor substrate of silicon carbide, and a temperature sensor portion. The semiconductor substrate includes a portion in which an n-type drift region and a p-type body region are laminated. The temperature sensor portion is disposed in the semiconductor substrate and is separated from the drift region by the body region. The temperature sensor portion includes an n-type cathode region being in contact with the body region, and a p-type anode region separated from the body region by the cathode region.

Provided is a semiconductor device comprising: a semiconductor substrate; a plurality of first trench portions formed at a front surface side of the semiconductor substrate and extending in a predetermined extending direction in a planar view; an emitter region of a first conductivity type formed between adjacent trenches of the plurality of first trench portions at the front surface side of the semiconductor substrate; a first contact region of a second conductivity type formed between the adjacent trenches of the plurality of first trench portions, the first contact region and the emitter region being arranged alternately in the extending direction; and a second contact region of a second conductivity type formed above the first contact region to be apart from the emitter region and having a higher doping concentration than the first contact region.

An RC IGBT with an n-barrier region in a transition section between a diode section and an IGBT section is presented.

To provide a semiconductor device that has barrier metal and has a small variation in a threshold voltage. A semiconductor device is provided, including a semiconductor substrate, an interlayer dielectric film arranged on an upper surface of the semiconductor substrate, a titanium layer provided on the interlayer dielectric film, and a titanium nitride layer provided on the titanium layer, where the interlayer dielectric film is provided with an opening that exposes a part of the upper surface of the semiconductor substrate, the titanium layer and the titanium nitride layer are also provided within the opening, and the titanium layer arranged in contact with the semiconductor substrate and on a bottom portion of the opening is entirely titanium-silicided.

A semiconductor device includes pads arrayed between a region where a transistor portion or a diode portion is disposed and a first end side on an upper surface of a semiconductor substrate, and a gate runner portion that transfers a gate voltage to the transistor portion. The gate runner portion has a first gate runner disposed passing between the first end side of the semiconductor substrate and at least one of the pads in the top view, and a second gate runner disposed passing between at least one of the pads and the transistor portion in the top view. The transistor portion is also disposed in the inter-pad regions, the gate trench portion disposed in the inter-pad regions is connected to the first gate runner, and the gate trench portion arranged so as to face the second gate runner is connected to the second gate runner.

Provided is a semiconductor device, including: a drift region of a first conductivity type which is provided in a semiconductor substrate, and a buffer region of the first conductivity type which is provided between the drift region and a lower surface of the semiconductor substrate, and has three or more concentration peaks higher than a doping concentration of the drift region of the semiconductor substrate in a depth direction. Three or more of the concentration peaks includes a shallowest peak closest to the lower surface of the semiconductor substrate, a high concentration peak arranged at an upper side than the lower surface of the semiconductor substrate than the shallowest peak, and one or more low concentration peaks arranged at an upper side than the lower surface of the semiconductor substrate than the high concentration peak and of which the doping concentration is ⅕ or less of the high concentration peak.

The disclosure provides dyes for marking hydrocarbon compositions. More particularly, the disclosure relates to non-mutagenic dyes for marking hydrocarbon com positions.

A semiconductor device includes a semiconductor body having a base region incorporating a field stop zone where the base region and the field stop zone are both formed using an epitaxial process. Furthermore, the epitaxial layer field stop zone is formed with an enhanced doping profile to realize improved soft-switching performance for the semiconductor device. In some embodiments, the enhanced doping profile includes multiple doped regions with peak doping levels where a first doped region adjacent to a first side of the field stop zone has a first peak doping level that is not higher than a last peak doping level of a last doped region adjacent to the base region. The epitaxial layer field stop zone of the present invention enables complex field stop zone doping profiles to be used to obtain the desired soft-switching characteristics in the semiconductor device.

This application provides a process for making a circuit of a bipolar junction transistor (BJT). The switchable short in one implementation of the invention is formed in a semiconductor wafer. A collector region is formed in the semiconductor wafer and inside of the collector region, a first base region is formed. An emitter region is formed inside the base region to form the BJT. A drain region is also formed inside the base region adjacent to the emitter region. A gate is formed over a portion of the base region adjacent to the drain region and the emitter region. The gate is connected to the collection region.

A semiconductor device includes pads arrayed between a region where a transistor portion or a diode portion is disposed and a first end side on an upper surface of a semiconductor substrate, and a gate runner portion that transfers a gate voltage to the transistor portion. The gate runner portion has a first gate runner disposed passing between the first end side of the semiconductor substrate and at least one of the pads in the top view, and a second gate runner disposed passing between at least one of the pads and the transistor portion in the top view. The transistor portion is also disposed in the inter-pad regions, the gate trench portion disposed in the inter-pad regions is connected to the first gate runner, and the gate trench portion arranged so as to face the second gate runner is connected to the second gate runner.