In a plan view of a semiconductor substrate, the semiconductor substrate includes a pillar exposing area in which the pillar region is exposed on the front surface of the semiconductor substrate, a pillar contacting area in which the pillar region is in contact with a deeper side of the anode contact region, and an anode contacting area in which the anode region is in contact with the deeper side of the anode contact region. In a direction along which the pillar contacting area and the anode contacting area are aligned, a width of the pillar contacting area is smaller than a width of the anode contacting area.

A transistor includes first and second load terminals and a semiconductor body coupled to both terminals. The semiconductor body includes: a drift region having dopants of a first conductivity type; a transistor section for conducting a forward load current and having a control head coupling the first load terminal to a first side of the drift region; and a diode section for conducting a reverse load current. A diode port couples the second load terminal to a second side of the drift region and includes: a first emitter electrically connected to the second load terminal and having dopants of the first conductivity type for injecting majority charge carriers into the drift region; and a second emitter having dopants of a second conductivity type for injecting minority charge carriers into the drift region. A pn-junction transition between the first and second emitters has a breakdown voltage of less than 10 V.

The present invention discloses a bi-mode insulated gate transistor, belonging to the technical filed of IGBTs. The bi-mode insulated gate transistor includes a reverse conducting region and a pilot region, wherein the reverse conducting region and the pilot region each include P+ collector regions, a drift region and a MOS cell region, the drift regions are disposed over the P+ collector regions, and the MOS cell regions are disposed over the drift regions; the reverse conducting region further includes N+ collector regions, and the N+ collector regions and the P+ collector regions are distributed alternatively; the pilot region further includes a separation region or a low-doped region, the separation region isolates the P+ collector regions of the pilot region from the P+ collector regions and the N+ collector regions of the reverse conducting region, and the low doped region is disposed over the P+ collector regions of the pilot region. In the present invention, the resistance of an electron current channel over the pilot region or a built-in potential of a PN junction of the collector of the pilot region is increased when a device works in a VDMOS mode, in order to reduce the size of the pilot region of the bi-mode insulated gate transistor, so that the uniformity of current intensity inside the device in work is increased, and the overall reliability of the device is further improved.

A semiconductor device includes a first load terminal at a first surface of a semiconductor body and a second load terminal at the opposing surface. An active device area is surrounded by an edge termination area. Load terminal contacts are absent in the edge termination area and are electrically connected to the semiconductor body in the active device area at the first surface. A positive temperature coefficient structure is between at least one of the first and second load terminals and a corresponding one of the first and second surfaces. Above a maximum operation temperature specified for the semiconductor device, a specific resistance of the positive temperature coefficient structure increases by at least two orders of magnitude within a temperature range of at most 50 K. A degree of area coverage of the positive temperature coefficient structure is greater in the edge termination area than in the active device area.

A method for manufacturing a semiconductor device, includes: (a) providing a SiC epitaxial substrate in which on a SiC support substrate, a SiC epitaxial growth layer having an impurity concentration equal to or less than 1/10,000 of that of the SiC support substrate and having a thickness of 50 m or more is disposed; (b) forming an impurity region, which forms a semiconductor element, on a first main surface of the SiC epitaxial substrate by selectively injecting impurity ions; (c) forming an ion implantation region, which controls warpage of the SiC epitaxial substrate, on a second main surface of the SiC epitaxial substrate by injecting predetermined ions; and (d) heating the SiC epitaxial substrate after (b) and (c).

An influence of a gate interference is suppressed and a reverse recovery property of a diode is improved. A diode includes a diode region located between the first boundary trench and the second boundary trench and a first and second IGBT regions. An emitter region and a body region are provided in each of the first and second IGBT regions. Each body region includes a body contact portion. An anode region is provided in the diode region. The anode region includes an anode contact portion. An interval between the first and second boundary trenches is equal to or longer than 200 m. An area ratio of the anode contact portion in the diode region is lower than each of an area ratio of the body contact portion in the first IGBT region and an area ratio of the body contact portion in the second IGBT region.

A semiconductor device is provided that can prevent a current from being concentrated into a specific chip, and can reduce loss as well as noise. The semiconductor device according to the present invention includes: a switching element; a main diode that is connected in parallel to the switching element; and an auxiliary diode that is connected in parallel to the switching element and has a different structure from that of the main diode, wherein in a conductive state a current flowing through the auxiliary diode is smaller than that through the main diode, and in a transition period from the conductive state to a non-conductive state a current flowing through the auxiliary diode is larger than that through the main diode.

A step of forming a silicon carbide substrate includes steps of: forming a first impurity region having a first conductivity type by epitaxial growth; forming an embedded region by performing ion implantation into the first impurity region, the embedded region having a second conductivity type different from the first conductivity type, the embedded region being disposed cyclically; and forming a second impurity region by epitaxial growth, the second impurity region being in contact with the first impurity region and the embedded region, the second impurity region having the second conductivity type, the second impurity region having an impurity concentration lower than an impurity concentration of the embedded region. A trench is formed to have a side portion and a bottom portion. The trench is disposed at the same cycle as the embedded region.

The invention includes a semiconductor device comprising an interlevel dielectric layer over a buried insulator layer over a semiconductor substrate; a source and drain in the interlevel layer; a channel between the source and drain, the channel including a first region having a first bandgap adjacent to a second region having a second bandgap, wherein the first band gap is larger than the second bandgap; and a gate over the channel.

The invention includes a semiconductor device comprising an interlevel dielectric layer over a buried insulator layer over a semiconductor substrate; a source and drain in the interlevel layer; a channel between the source and drain, the channel including a first region having a first bandgap adjacent to a second region having a second bandgap, wherein the first band gap is larger than the second bandgap; and a gate over the channel.