A method of manufacturing a semiconductor device includes: forming field electrode structures extending in a direction vertical to a first surface in a semiconductor body; forming cell mesas from portions of the semiconductor body between the field electrode structures, including body zones forming first pn junctions with a drift zone; forming gate structures between the field electrode structures and configured to control a current flow through the body zones; and forming auxiliary diode structures with a forward voltage lower than the first pn junctions and electrically connected in parallel with the first pn junctions, wherein semiconducting portions of the auxiliary diode structures are formed in the cell mesas.

The present disclosure relates to a power module that has a housing with an interior chamber and a plurality of switch modules interconnected to facilitate switching power to a load. Each of the plurality of switch modules comprises at least one transistor and at least one diode mounted within the interior chamber and both the at least one transistor and the at least one diode are majority carrier devices, are formed of a wide bandgap material system, or both. The switching modules may be arranged in virtually any fashion depending on the application. For example, the switching modules may be arranged in a six-pack, full H-bridge, half H-bridge, single switch or the like.

In a front surface of a semiconductor base body, a gate trench is disposed penetrating an n.sup.+-type source region and a p-type base region to a second n-type drift region. In the second n-type drift region, a p-type semiconductor region is selectively disposed. Between adjacent gate trenches, a contact trench is disposed penetrating the n.sup.+-type source region and the p-type base region, and going through the second n-type drift region to the p-type semiconductor region. A source electrode embedded in the contact trench contacts the p-type semiconductor region at a bottom portion and corner portion of the contact trench, and forms a Schottky junction with the second n-type drift region at a side wall of the contact trench.

Provided is a silicon carbide semiconductor device that enables integration of a transistor element and a Schottky barrier diode while avoiding the reduction of an active region. A silicon carbide semiconductor device includes a silicon carbide layer, a gate insulating film, a Schottky electrode being Schottky functioned to a drift layer via a first contact hole and an opening, a gate electrode being arranged on the gate insulating film, an insulating layer being arranged so as to cover the gate insulating film, the gate electrode, and the Schottky electrode and having a second contact hole for exposing the gate electrode, and a gate pad electrode being arranged on the insulating layer so as to overlap the Schottky electrode in a plan view and being electrically connected to the gate electrode via the second contact hole.

A synchronous rectifier is described that includes a transistor device that has a gate terminal, a source terminal, a drain terminal, and a field-plate electrode. The field-plate electrode of the transistor device includes an integrated diode. The integrated diode is configured to discharge a parasitic capacitance of the transistor device during each switching operation of the synchronous rectifier. In some examples, the integrated diode is also configured to charge the parasitic capacitance of the transistor device during each switching operation of the synchronous rectifier.

This invention discloses a method for manufacturing a semiconductor power device in a semiconductor substrate comprises an active cell area and a termination area. The method comprises the steps of a) growing and patterning a field oxide layer in the termination area and also in the active cell area on a top surface of the semiconductor substrate b) depositing and patterning a polysilicon layer on the top surface of the semiconductor substrate at a gap distance away from the field oxide layer; c) performing a blank body dopant implant to form body dopant regions in the semiconductor substrate substantially aligned with the gap area followed by diffusing the body dopant regions into body regions in the semiconductor substrate; d) implanting high concentration body-dopant regions encompassed in and having a higher dopant concentration than the body regions and e) applying a source mask to implant source regions having a conductivity opposite to the body region with the source regions encompassed in the body regions and surrounded by the high concentration body-dopant regions.

Disclosed is a technique capable of reducing loss at the time of switching in a diode. A diode disclosed in the present specification includes a cathode electrode, a cathode region made of a first conductivity type semiconductor, a drift region made of a low concentration first conductivity type semiconductor, an anode region made of a second conductivity type semiconductor, an anode electrode made of metal, a barrier region formed between the drift region and the anode region and made of a first conductivity type semiconductor having a concentration higher than that of the drift region, and a pillar region formed so as to connect the barrier region to the anode electrode and made of a first conductivity type semiconductor having a concentration higher than that of the barrier region. The pillar region and the anode are connected through a Schottky junction.

An SiC semiconductor device has a p type region including a low concentration region and a high concentration region filled in a trench formed in a cell region. A p type column is provided by the low concentration region, and a p.sup.+ type deep layer is provided by the high concentration region. Thus, since a SJ structure can be made by the p type column and the n type column provided by the n type drift layer, an on-state resistance can be reduced. As a drain potential can be blocked by the p.sup.+ type deep layer, at turnoff, an electric field applied to the gate insulation film can be alleviated and thus breakage of the gate insulation film can be restricted. Therefore, the SiC semiconductor device can realize the reduction of the on-state resistance and the restriction of breakage of the gate insulation film.

Semiconductor devices are formed using a thin epitaxial layer (nanotube) formed on sidewalls of dielectric-filled trenches. In one embodiment, a method for forming a semiconductor device includes forming a first epitaxial layer on sidewalls of trenches and forming second epitaxial layer on the first epitaxial layer where charges in the doped regions along the sidewalls of the first and second trenches achieve charge balance in operation. In another embodiment, the semiconductor device includes a termination structure including an array of termination cells.

A semiconductor device of an embodiment includes a p-type SiC layer; a SiC region provided on the p-type SiC layer and containing H (hydrogen) or D (deuterium) in an amount of 110.sup.18 cm.sup.3 or more and 110.sup.22 cm.sup.3 or less; and a metal layer provided on the SiC region.