Abstract: A method for producing a semiconductor device (20) is disclosed. The semiconductor device (20) includes: 1) a semiconductor substrate (1, 2), 2) a hetero semiconductor area (3) configured to contact a first main face (1A) of the semiconductor substrate (1, 2) and different from the semiconductor substrate (1, 2) in band gap, 3) a gate electrode (7) contacting, via a gate insulating film (6), a part of a junction part (13) between the hetero semiconductor area (3) and the semiconductor substrate (1, 2), 4) a source electrode (8) configured to connect to the hetero semiconductor area (3), and 5) a drain electrode (9) configured to make an ohmic connection with the semiconductor substrate (1, 2). The method includes the following sequential operations: i) forming the gate insulating film (6); and ii) nitriding the gate insulating film (6).

Abstract: An aspect of the present invention provides a semiconductor device that includes a first conductivity type semiconductor body, a source region in contact with the semiconductor body, whose bandgap is different from that of the semiconductor body, and which formed heterojunction with the semiconductor body, a gate insulating film in contact with a portion of junction between the source region and the semiconductor body, a gate electrode in contact with the gate insulating film, a source electrode, a low resistance region in contact with the source electrode and the source region, and connected ohmically with the source electrode, and a drain electrode connected ohmically with the semiconductor body.

Abstract: A trench is formed extending from a surface of a hetero semiconductor region of a polycrystal silicon to the drain region. Further, a driving point of the field effect transistor, where a gate insulating film, the hetero semiconductor region and the drain region are adjoined, is formed at a position spaced apart from a side wall of the trench.

Abstract: A semiconductor device includes: a semiconductor base; a hetero semiconductor region which is in contact with the semiconductor base and which has a band gap different from that of the semiconductor base; a first electrode connected to the hetero semiconductor region; and a second electrode forming an ohmic contact to the semiconductor base. The hetero semiconductor region includes a laminated hetero semiconductor region formed by laminating a plurality of semiconductor layers in which crystal alignment is discontinuous at a boundary between at least two layers.

Abstract: An aspect of the present invention provides a semiconductor device that includes a first conductivity type semiconductor body, a source region in contact with the semiconductor body, whose bandgap is different from that of the semiconductor body, and which formed heterojunction with the semiconductor body, a gate insulating film in contact with a portion of junction between the source region and the semiconductor body, a gate electrode in contact with the gate insulating film, a source electrode, a low resistance region in contact with the source electrode and the source region, and connected ohmically with the source electrode, and a drain electrode connected ohmically with the semiconductor body.

Abstract: Methods of manufacturing a semiconductor device including a semiconductor substrate and a hetero semiconductor region including a semiconductor material having a band gap different from that of the semiconductor substrate and contacting a portion of a first surface of the semiconductor substrate are taught herein, as are the resulting devices. The method comprises depositing a first insulating film on exposed portions of the first surface of the semiconductor substrate and on exposed surfaces of the hetero semiconductor material and forming a second insulating film between the first insulating film and facing surfaces of the semiconductor substrate and the hetero semiconductor region by performing a thermal treatment in an oxidizing atmosphere.

Abstract: An aspect of the present invention provides a semiconductor device that includes a first conductivity type semiconductor body, a source region in contact with the semiconductor body, whose bandgap is different from that of the semiconductor body, and which formed heterojunction with the semiconductor body, a gate insulating film in contact with a portion of junction between the source region and the semiconductor body, a gate electrode in contact with the gate insulating film, a source electrode, a low resistance region in contact with the source electrode and the source region, and connected ohmically with the source electrode, and a drain electrode connected ohmically with the semiconductor body.

Abstract: A semiconductor substrate made of a semiconductor material is prepared, and a hetero semiconductor region is formed on the semiconductor substrate to form a heterojunction in an interface between the hetero semiconductor region and the semiconductor substrate. The hetero semiconductor region is made of a semiconductor material having a bandgap different from that of the semiconductor material, and a part of the hetero semiconductor region includes a film thickness control portion whose film thickness is thinner than that of the other part thereof. By oxidizing the hetero semiconductor region with a thickness equal to the film thickness of the film thickness control portion, a gate insulating film adjacent to the heterojunction is formed. A gate electrode is formed on the gate insulating film. This makes it possible to manufacture a semiconductor device including the gate insulating film with a lower ON resistance, and with a higher insulating characteristic and reliability.

Abstract: A semiconductor substrate made of a semiconductor material is prepared, and a hetero semiconductor region is formed on the semiconductor substrate to form a heterojunction in an interface between the hetero semiconductor region and the semiconductor substrate. The hetero semiconductor region is made of a semiconductor material having a bandgap different from that of the semiconductor material, and a part of the hetero semiconductor region includes a film thickness control portion whose film thickness is thinner than that of the other part thereof. By oxidizing the hetero semiconductor region with a thickness equal to the film thickness of the film thickness control portion, a gate insulating film adjacent to the heterojunction is formed. A gate electrode is formed on the gate insulating film. This makes it possible to manufacture a semiconductor device including the gate insulating film with a lower ON resistance, and with a higher insulating characteristic and reliability.

Abstract: A semiconductor device with superior long-term reliability is disclosed that alleviates current concentration into a switch structure arranged at an outermost portion. The semiconductor device comprises hetero semiconductor regions formed of polycrystalline silicon having a band gap width different from that of a drift region and hetero-adjoined with the drift region, a gate insulation film, a gate electrode adjoined to the gate insulation film, a source electrode connected to a source contact portion of the hetero semiconductor regions and an outermost switch structure and a repeating portion switch structure with a drain electrode connected to a substrate region. In a conduction state, the outermost switch structure comprises a mechanism in which the current flowing at the outermost switch structure becomes smaller than the current flowing at the repeating portion switch structure.

Abstract: A hetero semiconductor corner region, which is a current-concentration relief region that keeps a reverse bias current from concentrating on the convex corner, is arranged in a hetero semiconductor region. Thereby, a current concentration on the convex corner can be prevented. As a result, an interrupting performance can be improved at the time of interruption, and at the same time, the generation of the hot spot where in a specific portion is prevented at the time of conduction to suppress deterioration in a specific portion, thereby ensuring a long-term reliability.

Abstract: A semiconductor substrate made of a semiconductor material is prepared, and a hetero semiconductor region is formed on the semiconductor substrate to form a heterojunction in an interface between the hetero semiconductor region and the semiconductor substrate. The hetero semiconductor region is made of a semiconductor material having a bandgap different from that of the semiconductor material, and a part of the hetero semiconductor region includes a film thickness control portion whose film thickness is thinner than that of the other part thereof. By oxidizing the hetero semiconductor region with a thickness equal to the film thickness of the film thickness control portion, a gate insulating film adjacent to the heterojunction is formed. A gate electrode is formed on the gate insulating film. This makes it possible to manufacture a semiconductor device including the gate insulating film with a lower ON resistance, and with a higher insulating characteristic and reliability.

Abstract: A semiconductor device is provided with: a semiconductor substrate of a predetermined electroconduction type; a hetero semiconductor region contacted with a first main surface of the semiconductor substrate and comprising a semiconductor material having a bandgap different from that of the semiconductor substrate; a gate electrode formed through a gate insulator layer at a position adjacent to a junction region between the hetero semiconductor region and the semiconductor substrate; a source electrode connected to the hetero semiconductor region; and a drain electrode connected to the semiconductor substrate; wherein the hetero semiconductor region includes a contact portion contacted with the source electrode, at least a partial region of the contact portion is of the same electroconduction type as the electroconduction type of the semiconductor substrate, and the partial region has an impurity concentration higher than an impurity concentration of at least that partial region of a gate-electrode facing port

Abstract: A semiconductor device is provided with a semiconductor region, a gate electrode, a source electrode and a drain electrode. The semiconductor region is formed on a semiconductor substrate surface and includes a first semiconductor portion of a first conducting type, a second semiconductor portion of a second conducting type, a band gap distinct from the substrate's band gap, more than two accumulated semiconductor layers, and junctions between the layers. The semiconductor layers each contain an impurity of the first conducting type. The gate electrode adjoins a heterojunction between the second semiconductor portion and the semiconductor substrate through a gate insulation film. The source electrode is coupled to the semiconductor region. The drain electrode is coupled to the semiconductor substrate.

Abstract: A method for producing a semiconductor device includes forming a first hetero-semiconductor layer as a hetero-junction to a surface of a silicon carbide epitaxial layer. This layer is composed of polycrystalline silicon having a band gap different from that of the silicon carbide epitaxial layer. An etching stopper layer composed of a material having a different etching rate from that of the polycrystalline silicon is formed on the surface of the first hetero-semiconductor layer. A second hetero-semiconductor layer composed of polycrystalline silicon is formed so that the second hetero-semiconductor layer contacts the surface of the first hetero-semiconductor layer and the etching stopper layer. The etching stopper layer is removed, the first hetero-semiconductor layer is thermally oxidized, and the thermally oxidized portion is then removed.

Abstract: Impurity concentration of a second semiconductor region is set such that when a predetermined reverse bias is applied to a heterojunction diode configured by a first semiconductor region and the second semiconductor region, a breakdown voltage at least in a heterojunction region other than outer peripheral ends of the heterojunction diode is a breakdown voltage of a semiconductor device.

Abstract: As semiconductor regions in contact with a first main surface of a semiconductor base composed by forming an N? silicon carbide epitaxial layer on an N+ silicon carbide substrate connected to a cathode electrode, there are provided both of an N+ polycrystalline silicon layer of a same conduction type as a conduction type of the semiconductor base and a P+ polycrystalline silicon layer of a conduction type different from the conduction type of the semiconductor base. Both of the N+ polycrystalline silicon layer and the P+ polycrystalline silicon layer are hetero-joined to the semiconductor base, and are ohmically connected to the anode electrode.

Abstract: A semiconductor device has a semiconductor base of a first conductivity type; a hetero semiconductor region in contact with the semiconductor base; a gate electrode adjacent to a portion of a junction between the hetero semiconductor region and the semiconductor base across a gate insulating film; a source electrode connected to the hetero semiconductor region; and a drain electrode connected to the semiconductor base. The hetero semiconductor region has a band gap different from that of the semiconductor base. The hetero semiconductor region includes a first hetero semiconductor region and a second hetero semiconductor region. The first hetero semiconductor region is formed before the gate insulating film is formed. The second hetero semiconductor region is formed after the gate insulating film is formed.

Abstract: A method of manufacturing a semiconductor device having a polycrystalline silicon layer (5) includes; a step of forming a mask layer (7) on the polycrystalline silicon layer (5); a step of forming a side wall (8) that is provided on a side face of the mask layer (7) and covers part of the polycrystalline silicon layer (6); a step of doping an impurity (52) into the polycrystalline silicon layer (5) by using at least one of the mask layer (7) and the side wall (8) as a mask; and a step of etching the polycrystalline silicon layer (5, 6) by using at least one of the mask layer (7) and the side wall (8) as a mask.

Abstract: A semiconductor device, includes: a first conductivity-semiconductor substrate; a hetero semiconductor region for forming a hetero junction with the first conductivity-semiconductor substrate; a gate electrode adjacent to a part of the hetero junction by way of a gate insulating film; a drain electrode connecting to the first conductivity-semiconductor substrate; a source electrode connecting to the hetero semiconductor region; and a second conductivity-semiconductor region formed on a part of a first face of the first conductivity-semiconductor substrate in such a configuration as to oppose the gate electrode via the gate insulating film, the gate insulating film, the hetero semiconductor region and the first conductivity-semiconductor substrate contacting each other to thereby form a triple contact point.