A semiconductor device may include: an n type of layer disposed on a first surface of a substrate; a p+ type of region disposed on the first surface of the substrate; a p type of region disposed at a top portion of the n type of layer; a first electrode disposed on the p+ type of region and the p type of region; and a second electrode disposed on a second surface of the substrate, wherein the side surface of the p+ type of region and the side surface of the n type of layer are in contact, and the thickness of the p+ type of region is the same as the thickness of the n type of layer and the thickness of the p type of region.

A method of manufacturing a semiconductor device includes: forming, on a surface of an n-type semiconductor layer, an impurity source film containing both aluminum and beryllium; and forming a p-type impurity-doped layer in the n-type semiconductor layer by irradiating the impurity source film with first laser light to simultaneously introduce the aluminum and the beryllium into the n-type semiconductor layer.

According to an embodiment of a semiconductor device, the semiconductor device includes a contact layer in contact with SiC material. The contact layer includes a metal nitride having a nitrogen content in a range of 10 to 50 atomic %. The semiconductor device further includes a non-ohmic contact formed between the SiC material and the contact layer.

A semiconductor device according to an embodiment includes a first electrode; a second electrode; a silicon carbide layer disposed between the first electrode and the second electrode; a first n-type silicon carbide region disposed in the silicon carbide layer; and a first nitrogen region disposed in the silicon carbide layer, the first nitrogen region disposed between the first n-type silicon carbide region and the first electrode, and the first nitrogen region having a first nitrogen concentration higher than a first n-type impurity concentration of the first n-type silicon carbide region.

Along dicing lines, cutting grooves that reach a rear surface from a front surface are formed by a first dicing blade in a semiconductor wafer, completely separating the semiconductor wafer into individual semiconductor chips by the cutting grooves. Thereafter, by a second dicing blade that is constituted by abrasive grains having a mean grit size smaller than that of the first dicing blade and that has a blade width wider than that of the first dicing blade, side walls of the cutting grooves, i.e., side surfaces of the semiconductor chips are polished, approaching a specular state.

A p-type oxide semiconductor is prevented from being oxidized by oxygen in an n-type oxide semiconductor even if the p-type oxide semiconductor is provided as a termination structure in the n-type oxide semiconductor. A semiconductor device includes an n-type gallium oxide substrate, an anode electrode joined to the n-type gallium oxide substrate, and a cathode electrode provided on the n-type gallium oxide substrate. Current flows between the anode electrode and the cathode electrode via the n-type gallium oxide substrate provided between the anode electrode and the cathode electrode. The semiconductor device further includes a p-type oxide semiconductor layer provided adjacent to a junction between the anode electrode and the n-type gallium oxide substrate, and a nitride layer provided between the p-type oxide semiconductor layer and the n-type gallium oxide substrate.

A semiconductor device includes a trench structure extending from a first surface into a semiconductor body composed of silicon carbide. The trench structure includes an electrode and between the electrode and the first surface a gate electrode. A shielding region adjoining the electrode forms a first pn junction with a drift structure formed in the semiconductor body. A Schottky contact is formed between the drift structure and a first contact structure.

A method of manufacturing a semiconductor device is provided with: implanting charged particles including oxygen into a surface of a SiC wafer; and forming a Schottky electrode that makes Schottky contact with the SiC wafer on the surface after the implantation of the charged particles.

A manufacturing method of an electronic device includes: forming a drift layer of an N type; forming a trench in the drift layer; forming an edge-termination structure alongside the trench by implanting dopant species of a P type; and forming a depression region between the trench and the edge-termination structure by digging the drift layer. The steps of forming the depression region and the trench are carried out at the same time. The step of forming the depression region comprises patterning the drift layer to form a structural connection with the edge-termination structure having a first slope, and the step of forming the trench comprises etching the drift layer to define side walls of the trench, which have a second slope steeper than the first slope.

A silicon carbide semiconductor device includes an n-type silicon carbide semiconductor substrate, a drain electrode electrically connected to a rear face, an n-type semiconductor layer having a second impurity concentration lower than the first impurity concentration, a p-type first semiconductor region, an n-type second semiconductor region, an n-type third semiconductor region, a trench having a first side face and a second side face opposing to each other and a third side face intersecting with the first side face and the second side face, a gate electrode formed in the trench with a gate insulating film interposed therebetween, a metal layer electrically connected to the third semiconductor region, and a source electrode electrically connecting the second semiconductor region and the metal layer to each other.