A method of manufacturing an insulated gate type switching device includes forming a gate trench that has a first portion with a first width in a first direction and a second portion with a second width in the first direction, the second width being wider than the first width. In an oblique implantation, second conductivity type impurities are irradiated at an irradiation angle inclined around an axis orthogonal to the first direction. The first width, the second width, and the irradiation angle are set such that the second conductivity type impurities are suppressed, at a first side surface of the first portion, from being implanted into a part below a lower end of a second semiconductor region, and at a second side surface of the second portion, the impurities are implanted into the part below the lower end of the second semiconductor region.

A method for removing crystal originated particles from a crystalline silicon body having opposite first and second surfaces includes increasing a surface area of at least one of the first and second surfaces. The method further includes oxidizing the increased surface area at a temperature of at least 1000 C. and for a duration of at least 20 minutes.

There is provided a trench-gate type semiconductor device that can prevent breakdown of a gate insulating film caused by a displacement current flowing into a protective diffusion layer at a portion of a trench underlying a gate electrode at a turn-off time and simultaneously improves a current density by narrowing a cell pitch. The semiconductor device has a gate electrode 7 embedded into a trench 5 penetrating a base region 3. The gate electrode 7 is disposed into a lattice shape in a planar view, and a protective diffusion layer 13 is formed in a drift layer 2a at the portion underlying thereof. At least one of blocks divided by the gate electrode 7 is a protective contact region 20 on which the trench 5 is entirely formed. A protective contact 21 for connecting the protective diffusion layer 13 at a bottom portion of the trench 5 and a source electrode 9 is disposed on the protective contact region 20.

A Reverse Bipolar Junction Transistor (RBJT) integrated circuit comprises a bipolar transistor and a parallel-connected distributed diode, where the base region is connected neither to the collector electrode nor to the emitter electrode. The bipolar transistor has unusually high emitter-to-base and emitter-to-collector reverse breakdown voltages. In the case of a PNP-type RBJT, an N base region extends into a P epitaxial layer, and a plurality of P++ collector regions extend into the base region. Each collector region is annular, and rings a corresponding diode cathode region. Parts of the epitaxial layer serve as the emitter, and other parts serve as the diode anode. Insulation features separate metal of the collector electrode from the base region, and from P type silicon of the epitaxial layer, so that the diode cathode is separated from the base region. This separation prevents base current leakage and reduces power dissipation during steady state on operation.

A Schottky barrier diode includes: an n+ type of silicon carbide substrate; an n type of epitaxial layer formed on a first surface of the n+ type of silicon carbide substrate; a plurality of p+ regions formed inside the n type of epitaxial layer; a Schottky electrode formed in an upper portion of the n type of epitaxial layer of an electrode region; and an ohmic electrode formed on a second surface of the n+ type of silicon carbide substrate, wherein the plurality of p+ regions are formed to be spaced apart from each other at a predetermined interval within the n type of epitaxial layer.

A method of fabricating a laterally diffused metal-oxide-semiconductor (LDMOS) transistor device having a bipolar transistor for electrostatic discharge (ESD) protection includes doping a substrate to form a body region of the LDMOS transistor device in the substrate, the body region having a first conductivity type, forming a doped isolating region of the LDMOS transistor device in the substrate, the doped isolating region having a second conductivity type and surrounding a device area of the LDMOS transistor device in which the body region is disposed, forming a base contact region of the bipolar transistor, the base contact region being disposed within the body region and having the first conductivity type, and doping the substrate to form an isolation contact region for the doped isolating region that defines a collector region of the bipolar transistor, to form source and drain regions of the LDMOS transistor device in the substrate, and to form an emitter region of the bipolar transistor within the body region.

In a silicon carbide semiconductor device, a p-type SiC layer is disposed in a corner of a bottom of a trench. Thus, even if an electric field is applied between a drain and a gate when a MOSFET is turned off, a depletion layer in a pn junction between the p-type SiC layer and an n.sup. type drift layer greatly extends toward the n.sup. type drift layer, and a high voltage caused by an influence of a drain voltage hardly enters a gate insulating film. Hence, an electric field concentration within the gate insulating film can be reduced, and the gate insulating film can be restricted from being broken. In this case, although the p-type SiC layer may be in a floating state, the p-type SiC layer is formed in only the corner of the bottom of the trench. Thus, the deterioration of the switching characteristic is relatively low.

A semiconductor device has an n-type buried layer formed by implanting antimony and/or arsenic into the p-type first epitaxial layer at a high dose and low energy, and implanting phosphorus at a low dose and high energy. A thermal drive process diffuses and activates both the heavy dopants and the phosphorus. The antimony and arsenic do not diffuse significantly, maintaining a narrow profile for a main layer of the buried layer. The phosphorus diffuses to provide a lightly-doped layer several microns thick below the main layer. An epitaxial p-type layer is grown over the buried layer.

III-nitride materials are generally described herein, including material structures comprising III-nitride material regions and silicon-containing substrates. Certain embodiments are related to gallium nitride materials and material structures comprising gallium nitride material regions and silicon-containing substrates.

A lateral bipolar junction transistor (LBJT) device that may include a dielectric stack including a pedestal of a base region passivating dielectric and a nucleation dielectric layer; and a base region composed of a germanium containing material or a type III-V semiconductor material in contact with the pedestal of the base region passivating dielectric. An emitter region and collector region may be present on opposing sides of the base region contacting a sidewall of the pedestal of the base region passivating dielectric and an upper surface of the nucleation dielectric layer.