A semiconductor device includes a switching device region including an active region having a first conductivity-type emitter region formed on an upper surface side of a first conductivity-type substrate, a second conductivity-type base region formed on an upper surface side of the substrate, a second conductivity-type collector layer formed on a lower surface side of the substrate, and a diode region having a second conductivity-type anode layer formed on the upper surface side of the substrate and a first conductivity-type cathode layer formed on the lower surface side of the substrate, wherein the cathode layer is separated from the active region when planarly viewed, and on an upper surface side of the active region, a second conductivity type high-concentration region having an impurity concentration higher than that of the anode layer is formed.

The invention includes a semiconductor device comprising an interlevel dielectric layer over a buried insulator layer over a semiconductor substrate; a source and drain in the interlevel layer; a channel between the source and drain, the channel including a first region having a first bandgap adjacent to a second region having a second bandgap, wherein the first band gap is larger than the second bandgap; and a gate over the channel.

A manufacturing method for reverse conducting insulated gate bipolar transistor, the manufacturing method is characterized by the use of polysilicon for filling in grooves on the back of a reverse conducting insulated gate bipolar transistor. The parameters of reverse conducting diodes on the back of the reverse conducting insulated gate bipolar transistor can be controlled simply by controlling the doping concentration of the polysilicon accurately, indicating relatively low requirements for process control. The reverse conducting insulated gate bipolar transistor manufacturing method is relatively low in requirements for process control and relatively small in manufacturing difficulty.

A method of manufacturing a semiconductor device, including preparing a semiconductor substrate having a main surface, forming a device element structure on the main surface, forming a protective film on the main surface of the semiconductor substrate to protect the device element structure, the protective film having an opening therein, forming at least one material film in a predetermined pattern on the main surface of the semiconductor substrate and in the opening of the protective film, the at least one material film being separate from the protective film by a distance of less than 1 mm, forming a resist film on the main surface of the semiconductor substrate, covering the protective film and the at least one material film, the resist film having an opening therein corresponding to an inducing region for impurity defects, and inducing the impurity defects in the semiconductor substrate, using the resist film as a mask.

There is provided a high withstand voltage LDMOS field-effect transistor that enables the compatibility of an increase of its withstand voltage and a decrease of its ON resistance. The high withstand voltage LDMOS is characterizing in including: a first electroconductive type body region formed on a main surface of a semiconductor substrate; a second electroconductive type source region formed on a surface of the body region; a second electroconductive type drift region formed so as to have contact with the body region; a second electroconductive type drain region formed on the drift region; a first electroconductive type buried region having contact with the body region and formed below the drift region; a gate electrode formed above the body region between the source region and the drift region and above the drift region nearer to the source region via a gate insulating film; a first field plate that extends from the gate electrode toward the drain region and that is formed above the drift region via a first insulating film; and a second field plate that has contact with the source region or the gate electrode and that is formed above the first field plate via a second insulating film, in which a distance between the buried region and the drain region is smaller than a distance between the first field plate and the drain region and larger than a distance between the second field plate and the drain region.

A semiconductor device includes an IGBT in an IGBT portion of a semiconductor body and a diode in a diode portion of the semiconductor body. The diode includes an anode region of a first conductivity type and confined by diode trenches along a first lateral direction. Each of the diode trenches includes a diode trench electrode and a diode trench dielectric. A first contact groove extends into the anode region along a vertical direction from the first surface of the semiconductor body. An anode contact region of the first conductivity type adjoins a bottom side of the first contact groove. A cathode contact region of a second conductivity type adjoins a second surface of the semiconductor body opposite to the first surface. The IGBT includes a gate trench including a gate electrode and a gate dielectric, a source region, an emitter electrode, a drift region, and a second contact groove.

A method of manufacturing a vertical power semiconductor device includes forming a drift region in a semiconductor body having a first main surface and a second main surface opposite to the first main surface along a vertical direction, the drift region including platinum atoms, and forming a field stop region in the semiconductor body between the drift region and the second main surface, the field stop region including a plurality of impurity peaks, wherein a first impurity peak of the plurality of impurity peaks is set a larger concentration than a second impurity peak of the plurality of impurity peaks, wherein the first impurity peak includes hydrogen and the second impurity peak includes helium.

A reverse conducting insulated gate bipolar transistor (IGBT) manufacturing method, comprising the following steps: providing a substrate having an IGBT structure formed on the front surface thereof; implanting P+ ions onto the back surface of the substrate; forming a channel on the back surface of the substrate through photolithography and etching processes; planarizing the back surface of the substrate through a laser scanning process to form P-type and N-type interval structures; and forming a back surface collector by conducting a back metalizing process on the back surface of the substrate. Laser scanning process can process only the back surface structure requiring annealing, thus solve the problem of the front surface structure of the reverse conducting IGBT restricting back surface annealing to a low temperature, improving the P-type and N-type impurity activation efficiency in the back surface structure of the reverse conducting IGBT, and enhancing the performance of the reverse conducting IGBT.

A semiconductor substrate is provided with a first cell region, the first cell region including: an n-type emitter region; a p-type first top body region; an n-type first barrier region; an n-type first pillar region; and a p-type first bottom body region, the semiconductor substrate may further comprise: an n-type drift region; a p-type collector region; an n-type cathode region, the n-type first barrier region may include a first peak position where a peak of the n-type impurity density is present within a part linked to the n-type first pillar region, and a second peak position where a peak of the n-type impurity density is present within a part in contact with the gate insulating layer, and a depth of the first peak position from a front surface of the semiconductor substrate is different from a depth of the second peak position from the front surface of the semiconductor substrate.

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.