The semiconductor device includes a chip which has a first surface on one side and a second surface on the other side, a plurality of IGBT regions which are provided at an interval in the chip, a boundary region which is provided in a region between the plurality of IGBT regions in the chip, a first conductivity type cathode region which is formed in a surface layer portion of the second surface in the boundary region, and a second conductivity type well region which is formed in a surface layer portion of the first surface in the boundary region.

A power semiconductor device comprises a semiconductor body, a gate electrode, and an extraction electrode, wherein the semiconductor body comprises a source region of a first conductivity type, well region of a second conductivity type different from the first conductivity type at the gate electrode, a drift region which is of the first conductivity type, and a barrier region which is of the first conductivity type, the barrier region is located between the drift region and the extraction electrode.

A power semiconductor device having a barrier region is provided. A power unit cell of the power semiconductor device has at least two trenches that may both extend into the barrier region. The at least two trenches may both have a respective trench electrode coupled to a control terminal of the power semiconductor device. For example, the trench electrodes are structured to reduce the total gate charge of the power semiconductor device. The barrier region may be p-doped and vertically confined, i.e., in and against the extension direction, by the drift region. The barrier region can be electrically floating.

A doping concentration distribution in an accumulation region in a depth direction of a semiconductor substrate has a maximum portion at which a doping concentration reaches a maximum value, an upper gradient portion in which the concentration decreases from the maximum portion to a base region, a lower gradient portion in which the concentration decreases from the maximum portion to a drift region, and a kink portion at which a differential value of the doping concentration distribution exhibits an extreme value in a region except a region in which the differential value exhibits a maximum value or a minimum value.

There is provided a semiconductor device including: a drift region of a first conductivity type disposed in a semiconductor substrate; a base region of a second conductivity type disposed above the drift region; an emitter region of the first conductivity type disposed above the base region; a plurality of trench portions arrayed in a predetermined array direction on a front surface side of the semiconductor substrate; a trench contact disposed on the front surface side of the semiconductor substrate between two adjacent trench portions; and a contact layer of the second conductivity type disposed under the trench contact and having a higher doping concentration than the base region, wherein a lower end of the trench contact is deeper than a lower end of the emitter region, and the emitter region and the contact layer are in contact with each other at a side wall of the trench contact.

A semiconductor apparatus includes a semiconductor substrate and a second electrode. Semiconductor substrate includes a device region and a peripheral region. An n.sup. drift region and second electrode extend from device region to peripheral region. An n buffer layer and a p collector layer are provided also in peripheral region. Peripheral region is provided with an n type region. N type region is in contact with second electrode and n buffer layer. The turn-off loss of the semiconductor apparatus is reduced.

Provided is a semiconductor device including: a semiconductor substrate including an active portion in which transistor portions and diode portions are alternately provided and provided with a plurality of trench portions extending in an extending direction of the transistor portion and the diode portion; an emitter electrode provided above a front surface of the semiconductor substrate; and a protective film of polyimide provided on an upper surface of the emitter electrode, wherein the diode portion includes a lifetime control region including a lifetime killer irradiated from a front surface side of the semiconductor substrate, wherein the active portion includes a protected region provided with the protective film and an unprotected region not provided with the protective film, and wherein the diode portion is included in the unprotected region and the protected region is included in the transistor portion.

A semiconductor device includes a chip that has a first main surface on one side and a second main surface on the other side, an IGBT region provided in an inner portion of the first main surface, an outer peripheral region provided in a peripheral edge portion of the first main surface, a first conductivity type well region formed in a surface layer portion of the first main surface in the outer peripheral region so as to define the IGBT region, an insulating film that covers the well region, a well connection electrode embedded in the insulating film so as to be connected to the well region, and a second conductivity type cathode region formed in a surface layer portion of the second main surface in the outer peripheral region so as to oppose the well connection electrode, and that forms a diode with the well region.

An SiC semiconductor device comprises: a chip that includes an SiC monocrystal and has a main surface; a trench structure that has a first side wall extending in an a-axis direction of the SiC monocrystal and a second side wall extending in an m-axis direction of the SiC monocrystal and is formed in the main surface; and a contact region of a first conductivity type that is formed in a region inside the chip along the trench structure at an interval in the m-axis direction from the first side wall.

We herein describe a semiconductor device comprising a first element portion formed on a substrate, the first element portion being an operating region of an insulated gate bipolar transistor (IGBT) and a second element portion formed on the substrate, the second element portion being an operating region of a diode. The first element portion comprises a first collector region of a second conductivity type, a drift region of a first conductivity type located over the first collector region, and formed by the semiconductor substrate, a first body region of a first conductivity type located over the drift region, a second body region of a second conductivity type located over the drift region, at least one first contact region of a first conductivity type located above the second body region and having a higher doping concentration compared to the first body region, at least one second contact region of a second conductivity type located laterally adjacent to the at least one first contact region, the at least one second contact region having a higher doping concentration than the second body region, a first plurality of trenches extending from a surface through the second body region of a second conductivity type into the drift region wherein the at least one first contact region adjoins at least one of the plurality of trenches so that, in use, a channel region is formed along said at least one trench of the first plurality of trenches and within the body region of a second conductivity type. A first trench of the first plurality of trenches is laterally spaced from a second trench of the first plurality of trenches by a first distance. The second element portion comprises a second collector region of a second conductivity type, the drift region of a first conductivity type located over the second collector region, a third body region of a second conductivity type located over the drift region, a second plurality of trenches extending from a surface through the third body region into the drift region. A first trench of the second plurality of trenches is laterally spaced from a second trench of the second plurality of trenches by a second distance, and the first distance is larger than the second distance. The semiconductor device further comprises a first terminal contact, wherein the first terminal contact is electrically connected to the at least one first contact region of a first conductivity type and the body region of a second conductivity type and a second terminal contact, wherein the second terminal contact is electrically connected to the first collector region and the second collector region.