Abstract: A diode includes the following: an n type semiconductor region; a p type semiconductor region provided in a part of a front face of the n type semiconductor region; an anode electrode (front face electrode) which adjoins a front face of the n type semiconductor region and a front face of the p type semiconductor region while at least forming a Schottky junction on a front face of the n type semiconductor region; and an insulating region which has a right-hand side (first side) and a left-hand side (second side) adjacent to the n type semiconductor region, the right-hand side facing a second n type semiconductor region which is located below the Schottky junction, the left-hand side facing a first n type semiconductor region which is located below a pn junction between the n type semiconductor region and the p type semiconductor region.

Abstract: A semiconductor device that includes an n-type semiconductor substrate and an upper electrode formed on an upper face of the semiconductor substrate and a method of manufacturing the semiconductor device are provided. A p-type semiconductor region is repeatedly formed in the semiconductor substrate in at least one direction parallel to the substrate plane so as to be exposed on an upper face of the semiconductor substrate. The upper electrode includes a metal electrode portion; and a semiconductor electrode portion made of a semiconductor material whose band gap is narrower than that of the semiconductor substrate. The semiconductor electrode portion is provided on each p-type semiconductor region exposed on the upper face of the semiconductor substrate. The metal electrode portion is in Schottky contact with an n-type semiconductor region exposed on the upper face of the semiconductor substrate, and is in ohmic contact with the semiconductor electrode portion.

Abstract: A semiconductor device is provided in which the contact resistance of the interface between an electrode and the semiconductor substrate is reduced. The semiconductor device includes a 4H polytype SiC substrate, and an electrode formed on a surface of the substrate. A 3C polytype layer, which extends obliquely relative to the surface of the substrate and whose end portion at the substrate surface is in contact with the electrode, is formed at the surface of the substrate. The 3C polytype layer has a lower bandgap than 4H polytype. Hence, electrons present in the 4H polytype region pass through the 3C polytype layer and reach the electrode. More precisely, the width of the passageway of the electrons is determined by the thickness of the 3C polytype layer. Consequently, with this semiconductor device, in which the passageway of the electrons is narrow, the electrons are able to reach the electrode at a speed close to the theoretical value, by the quantum wire effect.

Abstract: The invention provides a susceptor capable of obtaining high-quality SiC semiconductor crystals by keeping the Si concentration and C concentration around a wafer constant and by preventing the generation of particles. A susceptor of graphite covered with silicon carbide is characterized in that at least one section of a part on which a wafer is placed is tantalum carbide or a graphite material covered with tantalum carbide. The part on which the wafer is placed may be a detachable member. A material around the part on which the wafer is placed may be a detachable graphite material covered with silicon carbide.

Abstract: A susceptor used in semiconductor epitaxial growth that can simultaneously obtain a plurality of epitaxial films high in uniformity. The susceptor includes a barrel type susceptor having a plurality of surfaces on an outer side of each of which a plurality of substrates can be freely disposed, and a member that has the barrel type susceptor disposed inside thereof and surfaces each of which is oppositely disposed tilting in the same direction as each of the surfaces of the barrel type susceptor. Alternatively, a susceptor includes a barrel type susceptor having a plurality of surfaces on an inner side of each of which a plurality of substrates can be freely disposed, and a member that has the barrel type susceptor disposed at the peripheral portion thereof and surfaces each of which is oppositely disposed tilting in the same direction as each of the surfaces of the barrel type susceptor.

Abstract: Object information is read that denotes a load state of the object from storage and selects an object having a load that is lower than a predetermined value. Then, a reference to an object allocation control part is returned that allocates the selected object to a destination as a response through communicating means. In allocating an object, the object information is read from the storage to select an object having a load that is lower than a predetermined value. Then, a reference to a dispatcher is returned that executes the selected object to the destination as a response through the communicating means. In executing the object, the object information is read from the storage and executes the object if the object has a load that is lower than a predetermined threshold value.