A semiconductor device in which a transistor and a diode are formed on a common semiconductor substrate is provided. The semiconductor substrate includes a transistor region in which a transistor is formed and a diode region in which a diode is formed. At least one first electrode on a second main surface side of the transistor region and at least one second electrode on a second main surface side of the diode region are made of different materials.

Provided is a semiconductor device including a semiconductor substrate having a drift region; a transistor portion having a collector region; a diode portion having a cathode region; and a boundary portion arranged between the transistor portion and the diode portion at an upper surface of the semiconductor substrate, and having the collector region, wherein the mesa portion of each of the transistor portion and the boundary portion has an emitter region and a base region, the base region has a channel portion, and a density in the upper surface of the mesa portion in the region in which the channel portion is projected onto the upper surface of the mesa portion of the boundary portion may be smaller than the density of the region in which the channel portion is projected onto the upper surface of the mesa portion of the transistor portion.

Provided is a semiconductor device comprising: a semiconductor substrate; an active section provided in the semiconductor substrate; an edge termination structure section provided between the active section and an outer peripheral edge of the semiconductor substrate on an upper surface of the semiconductor substrate; and an end lifetime control unit that is provided in the semiconductor substrate in the edge termination structure section and is continuous in a range facing at least two or more diode sections arranged in the first direction, wherein the active section includes: a transistor section and the diode sections alternately arranged with the transistor section in a predetermined first direction on the upper surface of the semiconductor substrate.

A power semiconductor device includes a semiconductor body coupled to first and second load terminals. The body includes: at least a diode structure configured to conduct a load current between the terminals and including an anode port electrically connected to the first load terminal and a cathode port electrically connected to the second load terminal; and drift and field stop regions of the same conductivity type. The cathode port includes first port sections and second port sections with dopants of the opposite conductivity type. A transition between each of the second port sections and the field stop region forms a respective pn-junction that extends along a first lateral direction. A lateral separation distance between immediately adjacent ones of second port sections in a second group is smaller than in a first group.

A semiconductor device includes: a semiconductor substrate including a front surface, a back surface that is opposite to the front surface, and a drift layer of a first conductive type disposed between the front surface and the back surface; a first diffusion layer of a second conductive type provided between the drift layer and the front surface; a second diffusion layer provided between the drift layer and the back surface; a first buffer layer of the first conductive type provided between the drift layer and the second diffusion layer, having a concentration higher than that of the drift layer, and into which a proton is injected; and a second buffer layer of the first conductive type provided between the first buffer layer and the second diffusion layer and having a concentration higher than that of the drift layer, wherein a peak concentration of the second buffer layer is higher than a peak concentration of the first buffer layer, an impurity concentration of the first buffer layer gradually decreases toward the back surface, a length from a peak position of the first buffer layer to a boundary between the drift layer and the first buffer layer is represented by Xa, a length from the peak position to a boundary between the first buffer layer and the second buffer layer is represented by Xb, and Xb>5 Xa.

A semiconductor device includes: a semiconductor layer of a first conductivity type; a first electrode located on the semiconductor layer; a second electrode located on the semiconductor layer; a third electrode located on the semiconductor layer between the first electrode and the second electrode, and separated from them; a first semiconductor region that is located in the semiconductor layer and is of a second conductivity type; a first cathode region of the first conductivity type; a first anode region of the second conductivity type; a second cathode region of the first conductivity type; a second anode region of the second conductivity type; a third anode region of the second conductivity type; a third cathode region of the first conductivity type; a second semiconductor region of the second conductivity type; a fourth anode region of the second conductivity type; and a fourth cathode region of the first conductivity type.

A semiconductor device that can detect temperature appropriately is provided. A semiconductor device provided with a semiconductor substrate in which one or more transistor portions and one or more diode portions are provided is provided, including: a temperature detecting portion provided above the top surface of the semiconductor substrate and having a longitudinal side in a predetermined longitudinal direction; a top surface electrode provided above the top surface of the semiconductor substrate; and one or more external lines that have a connecting part connected with the top surface electrode and electrically connect the top surface electrode to a circuit outside the semiconductor device. The temperature detecting portion extends across the one or more transistor portions and the one or more diode portions in the longitudinal direction, and the connecting part of at least one of the external lines is arranged around the temperature detecting portion when seen from above.

A semiconductor device according to the present invention includes a substrate having an IGBT region, a diode region, and a high resistance region between the IGBT region and the diode region, a first electrode provided on an upper surface of the substrate and a second electrode provided on a back surface as a surface on an opposite side to the upper surface of the substrate, wherein in the high resistance region, a contact resistance between the upper surface of the substrate and the first electrode or a contact resistance between the back surface of the substrate and the second electrode is higher than in the diode region, and a width of the high resistance region is equal to or greater than a thickness of the substrate.

A high-voltage semiconductor device includes a substrate, a body region, a well region, a bulk region, a source, a drain, an isolation region, a gate structure, and a resistor. The body region and the well region are disposed in the substrate. The bulk region and the source are disposed in the body region. The drain is disposed in the well region. The isolation region is disposed on the well region. The isolation region is disposed between the drain and the source. The gate structure is disposed on the substrate. The gate structure extends onto a portion of the isolation region. The resistor is disposed on the isolation region. The resistor is electrically connected to the bulk region and the drain, or the resistor is electrically connected to the drain and/or the source.

A reverse conducting insulated gate power semiconductor device is provided which comprises a plurality of active unit cells (40) and a pilot diode unit cell (50) comprising a second conductivity type anode region (51) in direct contact with a first main electrode (21) and extending from a first main side (11) to a first depth (d1). Each active unit cell (40) comprises a first conductivity type first source layer (41a) in direct contact with the first main electrode (21), a second conductivity type base layer (42) and a first gate electrode (47a), which is separated from the first source layer (41a) and the second conductivity type base layer (42) by a first gate insulating layer (46a) to form a first field effect transistor structure. A lateral size (w) of the anode region (51) in an orthogonal projection onto a vertical plane perpendicular to the first main side (11) is equal to or less than 1 μm. On a first lateral side surface of the anode region (51) a first insulating layer (52a) is arranged and on an opposing second lateral side surface of the anode region (51) a second insulating layer (52b) is arranged. And a distance between the first insulating layer (52a) and the second insulating layer (52b) is equal to or less than 1 μm, the first insulating layer (52a) extending vertically from the first main side (11) to a second depth (d2), and the second insulating layer (52b) extending vertically from the first main side (11) to a third depth (d3), wherein the first depth (d1) is less than the second depth (d2) and less than the third depth (d3).