Provided is a composite substrate which has a high-performance semiconductor layer. A composite substrate of the present invention comprises: a supporting substrate which is formed of an insulating material; a semiconductor layer which is formed of a single crystal semiconductor that is superposed on and joined to the supporting substrate; and interfacial inclusions which are present in the interface between the supporting substrate and the semiconductor layer at a density of 10.sup.12 atoms/cm.sup.2 or less, and which are formed of a metal element that is different from the constituent elements of the supporting substrate and the semiconductor layer.

A method for forming a power semiconductor device is provided. The method includes providing a substrate having a first surface and a second surface; and forming a plurality of trenches in the second surface of the substrate. The method also includes forming a semiconductor pillar in each of the plurality of trenches, wherein the semiconductor pillars and the substrate form a plurality of super junctions of the power semiconductor device for increasing the breakdown voltage of the power semiconductor device and reducing the on-stage voltage of the power semiconductor device; and forming a gate structure on the first surface of the substrate. Further, the method includes forming a plurality of well regions in the first surface of the substrate around the gate structure; and forming a source region in each of the plurality of well regions around the gate structure.

A semiconductor device includes first and second semiconductor regions, and a third semiconductor region between the first and second semiconductor regions, wherein the dopant concentration of the third semiconductor region is greater than the dopant concentration of the second semiconductor region. The semiconductor device further includes a fourth semiconductor region selectively provided on an upper surface of the second semiconductor region, wherein a portion of the second semiconductor region is interposed between the third semiconductor region and the fourth semiconductor region, an insulating layer disposed on the second semiconductor region and the fourth semiconductor region and having an opening that exposes a portion of a top surface of the fourth semiconductor region, wherein the ratio of an area of opening to an area of the top surface is from 10% to 90%, and a wiring layer on the insulating layer and connected to the fourth semiconductor region via the opening.

A semiconductor device includes a transistor cell area with active transistor cells including source zones electrically connected to a first load electrode. The source zones have a first conductivity type. An edge area surrounds the active transistor cell area and includes an edge construction that includes straight sections and a corner section connecting neighboring straight sections. A second dopant ratio between a mean concentration of dopants of a complementary second conductivity type and a mean concentration of dopants of the first conductivity type in the corner section exceeds a first dopant ratio between a mean concentration of dopants of the second conductivity type and a mean concentration of dopants of the first conductivity type in the straight sections by at least 0.2% in relation to the first dopant ratio.

A method for manufacturing a semiconductor device includes providing a substrate structure comprising a substrate, a plurality of fins on the substrate and a hardmask on the fins, forming an insulating layer on the substrate structure covering the fins and the hardmask, removing a portion of the insulating layer by etching to expose the hardmask, removing the hardmask, and performing a fluorine ion implantation into a top portion of the fins. The implanted fluorine ions passivate dangling bonds in the top portion of the fins, thereby improving the reliability of the semiconductor device.

An epitaxial wafer for a heterojunction bipolar transistor and a heterojunction bipolar transistor that are capable of further reducing a turn-on voltage are provided. An epitaxial wafer for a heterojunction bipolar transistor includes a collector layer made of GaAs, a base layer formed on the collector layer and made of InGaAs, and an emitter layer formed on the base layer and made of InGaP, and the base layer has an In composition that decreases from the emitter layer side toward the collector layer side.

A semiconductor device according to an embodiment includes an n-type SiC region, an electrode in contact with the SiC region, and a region including oxygen, the region provided in the SiC region, the region being provided on an electrode side of the SiC region.

Semiconductor devices are formed using a thin epitaxial layer (nanotube) formed on sidewalls of dielectric-filled trenches. In one embodiment, a method for forming a semiconductor device includes forming a first epitaxial layer on sidewalls of trenches and forming second epitaxial layer on the first epitaxial layer where charges in the doped regions along the sidewalls of the first and second trenches achieve charge balance in operation. In another embodiment, the semiconductor device includes a termination structure including an array of termination cells.

An integrated circuit (IC) may include a semiconductor substrate, and a semiconductor resistor. The semiconductor resistor may include a well in the semiconductor substrate and having a first conductivity type, a first resistive region in the well having an L-shape and a second conductivity type, and a tuning element associated with the first resistive region. The IC may also include a resistance compensation circuit on the semiconductor substrate. The resistance compensation circuit may be configured to measure an initial resistance of the first resistive region, and generate a voltage at the tuning element to tune an operating resistance of the first resistive region based upon the measured initial resistance.

A Tunnel Field-Effect Transistor comprising a source-channel-drain structure, the source-channel-drain structure comprising a source region doped with a dopant element having a first dopant type and a first doping concentration; a drain region doped with a dopant element having a second dopant type opposite compared to the first dopant type, and a second doping concentration, a channel region situated between the source region and the drain region and having an intrinsic doping concentration, or lowly doped concentration being lower than the doping concentration of the source and drain regions, a gate stack comprising a gate electrode on a gate dielectric layer, the gate stack covering at least part of the channel region and extending at the source side up to at least an interface between the source region and the channel region, a drain extension region in the channel region or on top thereof, the drain extension region being formed from a material suitable for creating, and having a length/thickness ratio such that, in use, it creates a charged layer, in the OFF-state of the TFET, with a charge opposite to the charge of the majority carriers in the drain region.