A semiconductor device is proposed. The semiconductor device includes trenches extending into a semiconductor body from a first main surface. A first group of the trenches includes a gate electrode. A second group of the trenches includes a source electrode, the source electrode being subdivided into at least a first part and a second part. A conductance per unit length of the first part along a longitudinal direction of the source electrode is smaller than a conductance per unit length of the second part along the longitudinal direction of the source electrode, the second part being electrically coupled to a source contact area via the first part. A mesa region bounded by a trench of the first group and a trench of the second group includes a source region electrically connected to the source contact area.

A molding is formed by laminating an aggregate of SiC and a paste containing Si and C powders on an epitaxial layer of SiC formed on a support substrate of SiC to form an intermediate sintered body in which polycrystalline SiC is produced from the Si and C powders by reaction sintering, free Si is carbonized to SiC to form a sintered body layer, and the support substrate is removed from the epitaxial layer to form a semiconductor substrate in which the epitaxial layer and the sintered body layer are laminated.

A power semiconductor device includes: a semiconductor body with a drift region of a first conductivity type; a first load terminal at a first side of the semiconductor body; a second load terminal at a second side of the semiconductor body opposite the first side, the power semiconductor device configured to conduct a load current between the load terminals; a control terminal at the first side configured to receive a control signal for controlling the load current; within an active region at least partially surrounded by an edge termination region, first trenches laterally confining mesas for conducting the load current, having control trenches electrically connected to the control terminal, and arranged in accordance with a first average pitch; and in a region laterally overlapping the control terminal, second trenches arranged in accordance with a second average pitch different from the first average pitch and electrically connected to the control terminal.

A method for manufacturing an insulated gate bipolar transistor includes (a) providing a substrate comprising a front side and a back side; (b) forming at least one front side element and at least one front side metal layer on the front side of the substrate; (c) performing a thinning process on the back side of the substrate; (d) performing a laser pre-treatment process on the back side of the substrate; (e) performing at least one ion doping process on the back side of the substrate for forming at least one ion doping layer; (f) performing an annealing process on the back side of the substrate; and (g) forming a collector metal layer on the back side of the substrate.

A termination region of an IGBT is described, in which surface p-rings are combined with oxide/polysilicon-filled trenches, buried p-rings and surface field plates, so as to obtain an improved distribution of potential field lines in the termination region. The combination of surface ring termination and deep ring termination offers a significant reduction in the amount silicon area which is required for the termination region.

A method of producing a semiconductor device is disclosed in which, after proton implantation is performed, a hydrogen-induced donor is formed by a furnace annealing process to form an n-type field stop layer. A disorder generated in a proton passage region is reduced by a laser annealing process to form an n-type disorder reduction region. As such, the n-type field stop layer and the n-type disorder reduction region are formed by the proton implantation. Therefore, it is possible to provide a stable and inexpensive semiconductor device which has low conduction resistance and can improve electrical characteristics, such as a leakage current, and a method for producing the semiconductor device.

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.

A vertical drift metal-oxide-semiconductor (VDMOS) transistor with improved contact to source and body regions, and a method of fabricating the same. A masked ion implant of the source regions into opposite-type body regions defines the locations of body contact regions, which are implanted subsequently with a blanket implant. The surface of the source regions and body contact regions are silicide clad, and an overlying insulator layer deposited and planarized. Contact openings are formed through the planarized insulator layer, within which conductive plugs are formed to contact the metal silicide, and thus the source and body regions of the device. A metal conductor is formed overall to the desired thickness, and contacts the conductive plugs to provide bias to the source and body regions.

Proton irradiation is performed a plurality of times from rear surface of an n-type semiconductor substrate, which is an n.sup. drift layer, forming an n-type FS layer having lower resistance than the n-type semiconductor substrate in the rear surface of the n.sup. drift layer. When the proton irradiation is performed a plurality of times, the next proton irradiation is performed to as to compensate for a reduction in mobility due to disorder which remains after the previous proton irradiation. In this case, the second or subsequent proton irradiation is performed at the position of the disorder which is formed by the previous proton irradiation. In this way, even after proton irradiation and a heat treatment, the disorder is reduced and it is possible to prevent deterioration of characteristics, such as increase in leakage current. It is possible to form an n-type FS layer including a high-concentration hydrogen-related donor layer.

The present invention generally relates to a structure and manufacturing of a power field effect transistor (FET). The present invention provides a planar power metal oxide semiconductor field effect transistor (MOSFET) structure and an insulated gate bipolar transistor (IGBT) structure comprising a split gate and a semi-insulating field plate. The present invention also provides manufacturing methods of the structures.