A semiconductor device includes a substrate, an initial layer, and a superlattice stack. The initial layer is located on the substrate and includes aluminum nitride (AlN). The superlattice stack is located on the initial layer and includes a plurality of first films, a plurality of second films and at least one doped layer, and the first films and the second films are alternately stacked on the initial layer, wherein the at least one doped layer is arranged in one of the first films and the second films, and dopants of the at least one doped layer are selected from a group consisting of carbon, iron, and the combination thereof.

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 novel doping technology for semiconductor wafers has been developed, referred to as a quantum doping process that permits the deposition of only a fixed, controlled number of atoms in the form of a monolayer in a substitutional condition where only unterminated surface bonds react with the dopant, thus depositing only a number of atoms equal to the atomic surface density of the substrate material. This technique results in providing a quantized set of possible dopant concentration values that depend only on the additional number of layers of substrate material formed over the single layer of dopant atoms.

Protons are injected from a back surface side of a semiconductor substrate to repair both defects within the semiconductor substrate and also defects in a channel forming region on a front surface side of the semiconductor substrate. As a result, variation in gate threshold voltage is reduced and leak current when a reverse voltage is applied is reduced. Provided is a semiconductor device including a semiconductor substrate that includes an n-type impurity region containing protons, on a back surface side thereof; and a barrier metal that has an effect of shielding from protons, on a front surface side of the semiconductor substrate.

According to one embodiment, a semiconductor element includes a first nitride semiconductor region, a second nitride semiconductor region, and an intermediate region provided between the first nitride semiconductor region and the second nitride semiconductor region. A Si concentration in the intermediate region is not less than 110.sup.18/cm.sup.3 and not more than 110.sup.19/cm.sup.3. A charge density in the intermediate region is 310.sup.17/cm.sup.3 or less.

A method for manufacturing a semiconductor structure including following steps is provided. A dielectric layer is formed on a substrate. A polysilicon layer is formed on the dielectric layer. Ion implantation processes are performed to the polysilicon layer by using a fluorine dopant. Implantation depths of the ion implantation processes are different. A fluorine dopant concentration of the ion implantation process with a deeper implantation depth is smaller than a fluorine dopant concentration of the ion implantation process with a shallower implantation depth. After the ion implantation processes, a thermal process is performed to the polysilicon layer.

Semiconductor devices includes a thin epitaxial layer (nanotube) formed on sidewalls of mesas formed in a semiconductor layer. In one embodiment, a semiconductor device includes a first epitaxial layer and a second epitaxial layer formed on mesas of the semiconductor layer. The thicknesses and doping concentrations of the first and second epitaxial layers and the mesa are selected to achieve charge balance in operation. In another embodiment, the semiconductor body is lightly doped and the thicknesses and doping concentrations of the first and second epitaxial layers are selected to achieve charge balance in operation.

A semiconductor structure, device, or vertical field effect transistor is comprised of a drain, a drift layer disposed in a first direction relative to the drain and in electronic communication with the drain, a barrier layer disposed in the first direction relative to the drift layer and in electronic communication with the drain, the barrier layer comprising a current blocking layer and an aperture region, a two-dimensional hole gas-containing layer disposed in the first direction relative to the barrier layer, a gate electrode oriented to alter an energy level of the aperture region when a gate voltage is applied to the gate electrode, and a source in ohmic contact with the two-dimensional hole gas-containing layer. At least one of an additional layer, the drain, the drift region, the current blocking layer, the two-dimensional hole gas-containing layer, and the aperture region comprises diamond.

A semiconductor device includes a semiconductor structure including a first doped layer for forming a carrier channel having a carrier charge, a second doped layer having a conductivity type identical to a conductivity type of the first doped layer, a barrier layer arranged in proximity to the semiconductor structure via the second doped layer, wherein the barrier layer includes a partially doped layer having a conductivity type opposite to the conductivity type of the second doped layer, and a set of electrodes for providing and controlling the carrier charge in the carrier channel.

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.