A method of making a bipolar transistor includes patterning a first photoresist over a collector region of the bipolar transistor, the first photoresist defining a first opening. The method further includes performing a first implantation process through the first opening. The method further includes patterning a second photoresist over the collector region, the second photoresist defining a second opening different from the first opening. The method further includes performing a second implantation process through the second opening, wherein a dopant concentration resulting from the second implantation process is different from a dopant concentration resulting from the first implantation process.

This invention discloses a semiconductor power device disposed in a semiconductor substrate comprising a lightly doped layer formed on a heavily doped layer and having an active cell area and an edge termination area. The edge termination area comprises a plurality P-channel MOSFETs. By connecting the gate to the drain electrode, the P-channel MOSFET transistors formed on the edge termination are sequentially turned on when the applied voltage is equal to or greater than the threshold voltage Vt of the P-channel MOSFET transistors, thereby optimizing the voltage blocked by each region.

There are disclosed herein various implementations of a latch-up free power transistor. Such a device includes an insulated gate situated adjacent to a conduction channel in the power transistor, an emitter electrode in direct physical contact with the conduction channel, and a collector electrode in electrical contact with the conduction channel. The power transistor also includes an emitter layer in contact with a surface of a semiconductor substrate adjacent the conduction channel.

A semiconductor device includes an n.sup.+ type silicon carbide substrate, and in the substrate an active region where primary current flows and an edge termination area surrounding the active region. The semiconductor device has a first p-type region and a second p-type region in the edge termination area, and the first p-type region includes therein a plurality of third p-type regions, and the second p-type region includes therein a plurality of fourth p-type regions. The widths between the respective plurality of third p-type regions and the widths between the respective plurality of fourth p-type regions become greater further away from the active region.

A semiconductor module, an upper and lower arm kit, and a three-level inverter can be provided at low cost and with broad current ratings and voltage ratings using existing packages, without developing new packages. A first semiconductor module on an upper arm side and a second semiconductor module on a lower arm side are made using an existing package, and the semiconductor modules and are used to configure an upper and lower arm kit. Further, the upper and lower arm kit is used to configure a three-level inverter. These devices can be formed using existing packages, and semiconductor modules, the upper and lower arm kit, and the three-level inverter can be therefore provided at low cost and with broad current ratings and voltage ratings.

A dual channel trench LDMOS transistor includes a semiconductor layer of a first conductivity type formed on a substrate; a first trench formed in the semiconductor layer where a trench gate is formed in an upper portion of the first trench; a body region of the second conductivity type formed in the semiconductor layer adjacent the first trench; a source region of the first conductivity type formed in the body region and adjacent the first trench; a planar gate overlying the body region; a drain drift region of the first conductivity type formed in the semiconductor layer and in electrical contact with a drain electrode; and alternating N-type and P-type regions formed in the drain drift region with higher doping concentration than the drain-drift regions to form a super-junction structure in the drain drift region.

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.

A manufacturing method of a semiconductor device forms grooves on a surface side of a semiconductor substrate and thereafter performs grinding from a back side of the semiconductor substrate until a ground face reaches the grooves. Thereafter, a back electrode is formed on the back of the semiconductor substrate that is separated by the grinding.

A semiconductor device includes an annular-shaped first frame comprised of a ceramic and forming an inner cavity in which semiconductor elements are disposed. A first electrode is on one side and a second electrode is on another. A second frame in the inner cavity holds the semiconductor elements and is comprised of a resin. A first metallic member is on one side, has an annular shape, and connects the first frame and first electrode. A second metallic member is on the other side, has an annular shape, and connects the first frame and the second electrode. A first elastic body has a first portion between the first metallic member and the second frame and a second portion abutting an inner sidewall of the first frame or overlapping the first frame. A second elastic body has a first portion between the second metallic member and the second frame.

A silicon carbide (SiC) semiconductor element includes a semiconductor layer, a dielectric layer on a surface of the semiconductor layer, a gate electrode layer on the dielectric layer, a first doped region, a second doped region, a shallow doped region and a third doped region. The semiconductor layer is of a first conductivity type. The first doped region is of a second conductivity type and includes an upper doping boundary spaced from the surface by a first depth. The shallow doped region is of the second conductivity type, and extends from the surface to a shallow doped depth. The second doped region is adjacent to the shallow doped region and is at least partially in the first doped region. The third doped region is of the second conductivity type and at least partially overlaps the first doped region.