Abstract: In a silicon carbide semiconductor device such as a trench gate type power MOSFET, the film thickness and the impurity concentration of a thin film silicon carbide semiconductor layer formed on a trench side face to constitute an accumulation-type channel-forming region and enable the device to operate with a low gate voltage, low on-resistance and low power loss are set so that on impression of a reverse bias voltage a pn junction between a P-type epitaxial layer and an n.sup.- -type epitaxial layer undergoes avalanche breakdown before the thin film silicon carbide semiconductor layer undergoes punch-through. By this means it is possible to obtain a target high source-drain withstand voltage.

Abstract: A semiconductor device comprises a semiconductor substrate including a first conductivity type first semiconductor layer and a second conductivity type second semiconductor layer formed on the first semiconductor layer. A unit cell for controlling current flowing between a source electrode and a drain electrode is formed in the semiconductor substrate. A trench is formed in a peripheral region of the unit cell to form mesa structure. A field relaxing layer is formed between an insulating film on a side face of the second trench and both the first semiconductor layer and the second semiconductor layer in order to relax concentration of an electric field in the insulating film.

Abstract: A silicon carbide semiconductor device having a high blocking voltage, low loss, and a low threshold voltage is provided. An n.sup.+ type silicon carbide semiconductor substrate 1, an n.sup.- type silicon carbide semiconductor substrate 2, and a p type silicon carbide semiconductor layer 3 are successively laminated on top of one another. An n.sup.+ type source region 6 is formed in a predetermined region of the surface in the p type silicon carbide semiconductor layer 3, and a trench 9 is formed so as to extend through the n.sup.+ type source region 6 and the p type silicon carbide semiconductor layer 3 into the n.sup.- type silicon carbide semiconductor layer 2. A thin-film semiconductor layer (n type or p type) 11a is extendedly provided on the surface of the n.sup.+ type source region 6, the p type silicon carbide semiconductor layer 3, and the n.sup.- type silicon carbide semiconductor layer 2 in the side face of the trench 9.

Abstract: A silicon carbide semiconductor device having a high blocking voltage, low loss, and a low threshold voltage is provided. An n.sup.+ type silicon carbide semiconductor substrate 1, an n.sup.- type silicon carbide semiconductor substrate 2, and a p type silicon carbide semiconductor layer 3 are successively laminated on top of one another. An n.sup.+ type source region 6 is formed in a predetermined region of the surface in the p type silicon carbide semiconductor layer 3, and a trench 9 is formed so as to extend through the n.sup.+ type source region 6 and the p type silicon carbide semiconductor layer 3 into the n.sup.- type silicon carbide semiconductor layer 2. A thin-film semiconductor layer (n type or p type) 11a is extendedly provided on the surface of the n.sup.+ type source region 6, the p type silicon carbide semiconductor layer 3, and the n.sup.- type silicon carbide semiconductor layer 2 in the side face of the trench 9.

Abstract: A semiconductor device, which has an oxide laver with the thickness thereof being varied from portion to portion of the inner surface of a trench and can be easily produced, and a process of producing the same. An n.sup.+ type single crystal SiC substrate is formed of SiC of hexagonal system having a carbon face with a (0001) face orientation as a surface, and an n type epitaxial layer and a p type epitaxial layer are successively laminated onto the substrate. An n.sup.+ source region is provided within the p type epitaxial layer, and the trench extends through the source region and the epitaxial layer into the semiconductor substrate. The side face of the trench is almost perpendicular to the surface of the epitaxial layer with the bottom face of the trench having a plane parallel to the surface of the epitaxial layer. The thickness of a gate oxide layer, formed by thermal oxidation, on the bottom face of the trench is larger than the thickness of the gate oxide layer on the side face of the trench.

Abstract: A groove is formed on the surface of a semiconductor substrate composed of silicon carbide and a first thermal oxidation film is formed by executing thermal oxidation on a damaged layer of groove inner walls. Then, the first thermal oxidation film is removed so that the damaged layer can be removed. Since a second thermal oxidation film is formed after the damaged layer is removed, the second thermal oxidation film is uniform. A silicon carbide semiconductor device can be achieved with less side etching because substantially a (0001) carbon face of a cubic system is chosen as the plane orientation of the semiconductor substrate.