A semiconductor device includes a body zone in a semiconductor mesa, which is formed between neighboring control structures that extend from a first surface into a semiconductor body. A drift zone forms a first pn junction with the body zone. In the semiconductor mesa, the drift zone includes a first drift zone section that includes a constricted section of the semiconductor mesa. A minimum horizontal width of the constricted section parallel to the first surface is smaller than a maximum horizontal width of the body zone. An emitter layer between the drift zone and the second surface parallel to the first surface includes at least one first zone of a conductivity type of the drift zone.

A method of manufacturing a semiconductor device includes forming electrode trenches in a semiconductor substrate between semiconductor mesas that separate the electrode trenches, the semiconductor mesas including portions of a drift layer of a first conductivity type and a body layer of a second, complementary conductivity type between a first surface of the semiconductor substrate and the drift layer, respectively. The method further includes forming isolated source zones of the first conductivity type in the semiconductor mesas, the source zones extending from the first surface into the body layer. The method also includes forming separation structures in the semiconductor mesas between neighboring source zones arranged along an extension direction of the semiconductor mesas, the separation structures forming partial or complete constrictions of the semiconductor mesa, respectively.

A method of manufacturing a semiconductor device includes forming a first trench in a semiconductor substrate from a first side, forming a semiconductor layer adjoining the semiconductor substrate at the first side, the semiconductor layer capping the first trench at the first side, and forming a contact at a second side of the semiconductor substrate opposite to the first side.

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 method of manufacturing a semiconductor device includes forming a frame trench extending from a first surface into a base substrate, forming, in the frame trench, an edge termination structure comprising a glass structure, forming a conductive layer on the semiconductor substrate and the edge termination structure, and removing a portion of the conductive layer above the edge termination structure. A remnant portion of the conductive layer forms a conductive structure that covers a portion of the edge termination structure directly adjoining a sidewall of the frame trench.

A semiconductor device which solves the following problem of a super junction structure: due to a relatively high concentration in the body cell region (active region), in peripheral areas (peripheral regions or junction end regions), it is difficult to achieve a breakdown voltage equivalent to or higher than in the cell region through a conventional junction edge terminal structure or resurf structure. The semiconductor device includes a power MOSFET having a super junction structure formed in the cell region by a trench fill technique. Also, super junction structures having orientations parallel to the sides of the cell region are provided in a drift region around the cell region.

A method of manufacturing a semiconductor device includes: forming a first trench in a first area of a drift layer that has a surface including the first area and a second area; growing a crystal of a p-type base layer on a surface of the drift layer after forming the first trench; and growing a crystal of an n-type source layer on a surface of the base layer. Material of the drift layer, the base layer, and the source layer are a wide-gap semiconductor.

Impurity elements are doped at a high concentration exceeding a thermodynamic equilibrium concentration into a solid material having an extremely small diffusion coefficient of the impurity element. A method for doping impurities includes steps for depositing source film made of material containing impurity elements with a film thickness on a surface of a solid target object (semiconductor substrate) made from the solid material. The film thickness is determined in consideration of irradiation time per light pulse and the energy density of the light pulse. The method also includes a step for irradiating the source film by the light pulse with the irradiation time and the energy density so as to dope the impurity elements into the target object at a concentration exceeding a thermodynamic equilibrium concentration.

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).

Process for manufacturing a semiconductor power device, wherein a trench is formed in a semiconductor body having a first conductivity type; the trench is annealed for shaping purpose; and the trench is filled with semiconductor material via epitaxial growth so as to obtain a first column having a second conductivity type. The epitaxial growth is performed by supplying a gas containing silicon and a gas containing dopant ions of the second conductivity type in presence of a halogenide gas and occurs with uniform distribution of the dopant ions. The flow of the gas containing dopant ions is varied according to a linear ramp during the epitaxial growth; in particular, in the case of selective growth of the semiconductor material in the presence of a hard mask, the flow decreases; in the case of non-selective growth, in the absence of hard mask, the flow increases.