An interlayer insulating film covers a gate electrode and a gate insulating film embedded in a trench. A source electrode includes a first TiN film, a NiSi film, a Ti film, a second TiN film, and an Al alloy film. The first TiN film covers a part of the interlayer insulating film so as to not contact a semiconductor substrate at a bottom of a contact hole. The NiSi film forms an ohmic contact with the semiconductor substrate in the contact hole. The Ti film, the second TiN film, and the Al alloy film are sequentially stacked on surfaces of the first TiN film and the NiSi film, spanning a front surface of the semiconductor substrate, from on the interlayer insulating film. A terminal pin is soldered to the source electrode 16, in an upright position orthogonal to the front surface of the semiconductor substrate.

At bottom of a gate trench, a conductive layer is provided. A Schottky junction is formed along a side wall of the gate trench by the conductive layer and the n-type current spreading region. The Schottky junction constitutes one unit cell of a trench-type SBD. In the gate trench, a gate electrode is provided on the conductive layer, via an insulating layer. The gate electrode constitutes one unit cell of a trench-gate-type vertical MOSFET. In other words, one unit cell of the trench gate MOSFET and one unit cell of the trench-type SBD are disposed built into a single gate trench and oppose each other in a depth direction.

According to one embodiment, a method for manufacturing a device includes a first process, a second process, a third process, and a fourth process. The first process includes providing a structure body at a first surface of a substrate. The substrate is light-transmissive and has a second surface. A light transmissivity of the structure body is lower than a light transmissivity of the substrate. The second process includes providing a negative-type photoresist at the second surface. The third process includes irradiating the substrate with light to expose a portion of the photoresist. The light is irradiated in a first direction from the first surface toward the second surface. The light passes through the substrate. The fourth process includes developing the photoresist to remain the portion of the photoresist in a state of being adhered to the second surface and to remove other portion of the photoresist.

A method for fabricating an optical element is provided. The fabrication method includes the following steps. A substrate is provided. A plurality of metal grids are formed on the substrate. A first organic layer is formed on the substrate between the plurality of metal grids. A second organic layer is formed on the first organic layer and the plurality of metal grids. The second organic layer and the first organic layer are etched to leave the plurality of metal grids and a plurality of patterned second organic layers on the plurality of metal grids. An optical element fabricated by the method is also provided.

A semiconductor device includes a semiconductor substrate, and a semiconductor layer disposed on the semiconductor substrate. First and second pillar layers, of respective first and second conductivity types, are alternately provided in a direction in parallel with a main surface in an active region of the semiconductor layer and in a termination region. A pillar pitch in the termination region is set to be larger than a pillar pitch in the active region. A product of a width of one of the first pillar layers and effective impurity concentration of the first conductivity of the one of the first pillar layers is equal to a product of a width of one of the second pillar layers and effective impurity concentration of the second conductivity of the one of the second pillar layers.

A GaN on diamond wafer and method for manufacturing the same is provided. The method comprising: disposing a GaN device or wafer on a substrate, having a nucleation layer disposed between the substrate and a GaN layer; affixing the device to a handling wafer; removing the substrate and substantially all the nucleation layer; and bonding the GaN layer to a diamond substrate.

A method for manufacturing a semiconductor device having an SiC-IGBT and an SiC-MOSFET in a single semiconductor chip, including forming a second conductive-type SiC base layer on a substrate, and selectively implanting first and second conductive-type impurities into surfaces of the substrate and base layer to form a collector region, a channel region in a surficial portion of the SiC base layer, and an emitter region in a surficial portion of the channel region, the emitter region serving also as a source region of the SiC-MOSFET.

A method of forming a semiconductor device includes forming a trench in a semiconductor body; at least partially filling the trench with a filling material; introducing dopants into a portion of the filling material; and applying a first thermal processing to the semiconductor body to spread the dopants in the filling material along a vertical direction of the filling material by a diffusion process. The vertical doping profile of the dopants within the doped filling material is shaped during the first thermal processing. Additionally, the dopants are substantially confined to within the trench and substantially do not diffuse from the doped filling material into the semiconductor body during the first thermal processing. A second thermal processing is applied to the semiconductor body after the first thermal processing to cause diffusion of the dopants from the doped filling material into the semiconductor body adjoining the trench.

All of intervals between adjacent p type guard rings are set to be equal to or less than an interval between p type deep layers. As a result, the interval between the p type guard rings becomes large, i.e., the trenches are formed sparsely, so that the p type layer is prevented from being formed thick at the guard ring portion when the p type layer is epitaxially grown. Therefore, by removing the p type layer in the cell portion at the time of the etch back process, it is possible to remove the p type layer without leaving any residue in the guard ring portion. Therefore, when forming the p type deep layer, the p type guard ring and the p type connection layer by etching back the p type layer, the residue of the p type layer is restricted from remaining in the guard ring portion.

A silicon carbide semiconductor device includes an active region, a first-conductivity-type region, and a termination region. The active region has first second-conductivity-type regions and first silicide films in trenches, second second-conductivity-type regions and a second silicide film between the trenches that are adjacent to one another, and a first electrode while the termination region has a third second-conductivity-type region. The active region includes ohmic regions, non-operating regions and Schottky regions, each of which has a stripe shape. Each ohmic region is a region where the first electrode is in contact with either the first silicide film or the second silicide film. Each non-operating region is a region where the first electrode is in contact with either the first or second second-conductivity-type regions. Each Schottky region is a region where the first electrode forms a Schottky barrier junction with the first-conductivity-type region.