Abstract: A semiconductor device includes an n-type first guard ring layer provided between an emitter layer and a collector layer on a surface side of a base layer, and having a higher n-type impurity concentration than the base layer, and an n-type second guard ring layer provided between the first guard ring layer and a buried layer, connected to the first guard ring layer and the buried layer, and having a higher n-type impurity concentration than the base layer. The first guard ring layer has an n-type impurity concentration profile decreasing toward the second guard ring layer side, and the second guard ring layer has an impurity concentration profile decreasing toward the first guard ring layer side.

Abstract: In a method of manufacturing a semiconductor device, a semiconductor substrate of a first conductivity type having first and second surfaces is prepared. Second conductivity type impurities for forming a collector layer are implanted to the second surface using a mask that has an opening at a portion where the collector layer will be formed. An oxide layer is formed by enhanced-oxidizing the collector layer. First conductivity type impurities for forming a first conductivity type layer are implanted to the second surface using the oxide layer as a mask. A support base is attached to the second surface and a thickness of the semiconductor substrate is reduced from the first surface. An element part including a base region, an emitter region, a plurality of trenches, a gate insulating layer, a gate electrode, and a first electrode is formed on the first surface of the semiconductor substrate.

Abstract: In a method of manufacturing a semiconductor device, a semiconductor substrate of a first conductivity type having first and second surfaces is prepared. Second conductivity type impurities for forming a collector layer are implanted to the second surface using a mask that has an opening at a portion where the collector layer will be formed. An oxide layer is formed by enhanced-oxidizing the collector layer. First conductivity type impurities for forming a first conductivity type layer are implanted to the second surface using the oxide layer as a mask. A support base is attached to the second surface and a thickness of the semiconductor substrate is reduced from the first surface. An element part including a base region, an emitter region, a plurality of trenches, a gate insulating layer, a gate electrode, and a first electrode is formed on the first surface of the semiconductor substrate.

Abstract: A p-type collector region of an IGBT and an n-type cathode region of a free wheel diode are alternately formed in a second main surface of a semiconductor substrate. A back electrode is formed on the second main surface so as to be in contact with both of the p-type collector region and the n-type cathode region, and has a titanium layer, a nickel layer and a gold layer that are successively stacked from the side of the second main surface. A semiconductor device capable of obtaining a satisfactory ON voltage in any of conduction of an insulated gate field effect transistor and conduction of the free wheel diode as well as a manufacturing method thereof can thus be obtained.

Abstract: A vertical BJT which has a maximal current gain for a photodiode area. According to embodiments, since the BJT can be formed together with the photodiode, and collector current flows up and down based on the double base structure, the magnitude of the current may be increased.

Abstract: A method for fabricating a 3-D monolithic memory device. Silicon-oxynitride (SixOyNz) on amorphous carbon is used an effective, easily removable hard mask with high selectivity to silicon, oxide, and tungsten. A silicon-oxynitride layer is etched using a photoresist layer, and the resulting etched SixOyNz layer is used to etch an amorphous carbon layer. Silicon, oxide, and/or tungsten layers are etched using the amorphous carbon layer. In one implementation, conductive rails of the 3-D monolithic memory device are formed by etching an oxide layer such as silicon dioxide (SiO2) using the patterned amorphous carbon layer as a hard mask. Memory cell diodes are formed as pillars in polysilicon between the conductive rails by etching a polysilicon layer using another patterned amorphous carbon layer as a hard mask. Additional levels of conductive rails and memory cell diodes are formed similarly to build the 3-D monolithic memory device.

Abstract: A vertical IMOS-type transistor including: a stack of a first semiconductor portion doped with dopant elements of a first type, of a second substantially undoped intrinsic semiconductor portion, and of a third semiconductor portion doped with dopant elements of a second type forming a PIN-type diode; and a conductive gate placed against the stack with an interposed insulating layer.

Abstract: In a semiconductor device having a pair of IGBT and diode which are connected to each other in inverse-parallel in which a collector-electrode of the IGBT and a cathode-electrode of the diode are wired to each other, and an emitter-electrode of the IGBT and an anode-electrode of the diode are wired to each other, when a breakdown voltage of a junction of a p-type emitter layer and an n-type buffer layer of the IGBT is represented as BVec, and a forward voltage occurring while the diode transits from a state of blocking to a state of forward conduction is represented as VF, a relationship of VF<BVec is satisfied in a predetermined current value Id of a current flowing in the diode, and the maximal doping concentration of the n-type cathode layer of the diode is higher than that of the n-type buffer layer of the IGBT.

Abstract: A vertical field effect transistor includes: an active region with a bundle of linear structures functioning as a channel region; a lower electrode, functioning as one of source and drain regions; an upper electrode, functioning as the other of the source and drain regions; a gate electrode for controlling the electric conductivity of at least a portion of the bundle of linear structures included in the active region; and a gate insulating film arranged between the active region and the gate electrode to electrically isolate the gate electrode from the bundle of linear structures. The transistor further includes a dielectric portion between the upper and lower electrodes. The upper electrode is located over the lower electrode with the dielectric portion interposed and includes an overhanging portion sticking out laterally from over the dielectric portion. The active region is located right under the overhanging portion of the upper electrode.