This invention discloses a semiconductor device disposed in a semiconductor substrate. The semiconductor device includes a first semiconductor layer of a first conductivity type on a first major surface. The semiconductor device further includes a second semiconductor layer of a second conductivity type on a second major surface opposite the first major surface. The semiconductor device further includes an injection efficiency controlling buffer layer of a first conductivity type disposed immediately below the second semiconductor layer to control the injection efficiency of the second semiconductor layer.

A vertical power component includes a silicon substrate of a first conductivity type with a well of the second conductivity type on a lower surface of the substrate. The first well is bordered at a component periphery with an insulating porous silicon ring. An upper surface of the porous silicon ring is only in contact with the substrate of the first conductivity type. The insulating porous silicon ring penetrates into the substrate down to a depth greater than a thickness of the well. The porous silicon ring is produced by forming a doped well in a first surface of a doped substrate, placing that first surface of the substrate into an electrolytic bath, and circulating a current between an opposite second surface of the substrate and the electrolytic bath.

A die stack assembly includes first and second power semiconductor device dice. The first die has a P type peripheral edge separation structure that extends from the top planar semiconductor surface of the first die all the way to the bottom planar semiconductor surface of the die, and that is doped at least in part with aluminum. The backside of the first die is mounted to the backside of the second die. A metal feature that is not covered with passivation, and that can serve as a bonding pad, is disposed on part of the peripheral edge separation structure. A metal member (for example, a bond wire or metal clip) contacts the metal feature such that an electrical connection is established from the metal member, through the metal feature, through the peripheral edge separation structure of the first die, and to an electrode of the second die.

A chip part includes a substrate, an element formed on the substrate, and an electrode formed on the substrate. A recess and/or projection expressing information related to the element is formed at a peripheral edge portion of the substrate.

A high-voltage semiconductor structure including a substrate, a first doped region, a well, a second doped region, a third doped region, a fourth doped region, and a gate structure is provided. The substrate has a first conductive type. The first doped region has the first conductive type and is formed in the substrate. The well has a second conductive type and is formed in the substrate. The second doped region has the second conductive type and is formed in the first doped region. The third doped region has the first conductive type and is formed in the well. The fourth doped region has the second conductive type and is formed in the well. The gate structure is disposed over the substrate and partially covers the first doped region and the well.

According to an embodiment, a semiconductor device is provided. The device includes a second region having a greater curvature than a first region. The device includes an epitaxy layer of a first conductivity type, a well of a second conductivity type in the epitaxy layer, a drain in the epitaxy layer, a source in the well, and a bulk in the well and in contact with the source, the bulk having a greater area in the second region than in the first region.

A highly reliable semiconductor device with high withstand voltage is provided. As means therefor, an impurity concentration in a first JTE region is set to 4.410.sup.17 cm.sup.3 or higher and 610.sup.17 cm.sup.3 or lower and an impurity concentration in a second JTE region is set to 210.sup.17 cm.sup.3 or lower in a case of a Schottky diode, and an impurity concentration in the first JTE region is set to 610.sup.17 cm.sup.3 or higher and 810.sup.17 cm.sup.3 or lower and an impurity concentration in the second JTE region is set to 210.sup.17 cm.sup.3 or lower in a case of a junction barrier Schottky diode.

An insulated gate semiconductor device provided herein includes a front electrode and a rear electrode and is configured to switch a conducting path between the front electrode and the rear electrode. The insulated gate semiconductor device includes a first circumferential trench provided in the front surface; a second circumferential trend provided in the front surface and deeper than the first circumferential trench; a fifth region of a second conductivity type exposed on a bottom surface of the first circumferential trench; a sixth region of the second conductivity type exposed on a bottom surface of the second circumferential trench; and a seventh region of a first conductivity type connected to the third region and separating the fifth region from the sixth region. A front side end portion of the sixth region being located on a rear side with respect to a rear side end portion of the fifth region.

Provided are a power device having an improved field stop layer and a method of manufacturing the same. The method can include performing a first ion implant process by implanting impurity ions of a first conductive type into a front surface of a semiconductor substrate to form an implanted field stop layer where the semiconductor substrate is the first conductive type. The method can include performing a second ion implant process by implanting impurity ions of the first conductive type into a first part of the implanted field stop layer such that an impurity concentration of the first part of the implanted field stop layer is higher than an impurity concentration of a second part of the implanted field stop layer.

A semiconductor device capable of carrying out temperature detection appropriately by a temperature sensor is provided. In a semiconductor device disclosed herein, a first width of a first portion within a front surface insulating film (that is, part located in an upper part of an active region among a part extending along a first side of a front surface electrode that is closer to the temperature sensor) is wider than a second width of a second portion within the front surface insulating film (that is, part located in the upper part of the active region among a part extending along a second side of the front surface electrode).