A p-type Tunnel Field-Effect Transistor comprises a drain p-type semiconductor region, a source n-type semiconductor region, and at least one gate stack. The source n-type semiconductor region comprises a lowly doped section with a length of at least 10 nm and with a doping level of n-type dopant elements below 510.sup.18 at/cm.sup.3 and, in contact with the lowly doped section, a highly doped section with a length between 1 monolayer and 20 nm and with a doping level of n-type dopant elements above 510.sup.18 at/cm.sup.3.

Semiconductor devices are formed using a pair of thin epitaxial layers (nanotubes) of opposite conductivity type formed on sidewalls of dielectric-filled trenches. In one embodiment, a termination structure is formed in the termination area and includes a first termination cell formed in the termination area at an interface to the active area, the termination cell being formed in a mesa of the first semiconductor layer and having a first width; and an end termination cell being formed next to the first termination cell in the termination area, the end termination cell being formed in an end mesa of the first semiconductor layer and having a second width greater than the first width.

A semiconductor device is disclosed in which proton implantation is performed a plurality of times to form a plurality of n-type buffer layers in an n-type drift layer at different depths from a rear surface of a substrate. The depth of the n-type buffer layer, which is provided at the deepest position from the rear surface of the substrate, from the rear surface of the substrate is more than 15 m. The temperature of a heat treatment which is performed in order to change a proton into a donor and to recover a crystal defect after the proton implantation is equal to or higher than 400 C. In a carrier concentration distribution of the n-type buffer layer, a width from the peak position of carrier concentration to an anode is more than a width from the peak position to a cathode.

A III-nitride tunnel junction with a modified p-n interface, wherein the modified p-n interface includes a delta-doped layer to reduce tunneling resistance. The delta-doped layer may be doped using donor atoms comprised of Oxygen (O), Germanium (Ge) or Silicon (Si); acceptor atoms comprised of Magnesium (Mg) or Zinc (Zn); or impurities comprised of Iron (Fe) or Carbon (C).

A semiconductor structure including a substrate, a dielectric layer and a polysilicon layer is provided. The dielectric layer is disposed on the substrate. The polysilicon layer is disposed on the dielectric layer. A fluorine dopant concentration in the polysilicon layer presents Gaussian distributions from a top portion to a bottom portion of the polysilicon layer. Fluorine dopant peak concentrations of the Gaussian distributions are progressively decreased from the top portion to the bottom portion of the polysilicon layer.

A SiC epitaxial wafer of the present invention includes a SiC single crystal substrate, and a high concentration layer that is provided on the SiC single crystal substrate and has an average value of an n-type doping concentration of 1?10.sup.18/cm.sup.3 or more and 1?10.sup.19/cm.sup.3 or less, and in-plane uniformity of the doping concentration of 30% or less.

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 semiconductor element includes a Molecular Beam Epitaxy (MBE)-grown channel layer including a -Ga.sub.2O.sub.3 single crystal layer. The MBE-grown channel layer is formed on a -Ga.sub.2O.sub.3 single crystal substrate.

A heterostructure includes a substrate; an intermediate layer disposed on the substrate; and a group III-V layer having a first primary surface disposed on the intermediate layer and a dopant concentration that varies in a manner including a plurality of ramps with at least one of increasing dopant concentration and decreasing dopant concentration, along the growth direction from the first primary surface throughout the layer's thickness before terminating in a second primary surface.

An electronic chip including a plurality of buried doped bars and a circuit for detecting an anomaly of an electric characteristic of the bars.