A method of forming semiconductor devices may begin with forming gate structures over fin structures on sidewalls of at least two mandrels. The mandrels are removed to provide gate structures having a first pitch and gate structure spacers having a second pitch. A first conductivity type epitaxial semiconductor material is formed on the exposed portions of the fin structures. Masking is formed in the first pitch space. The first conductivity type epitaxial semiconductor material is removed from a second space pitch. A second conductivity type epitaxial semiconductor material is formed in the second space pitch.

A semiconductor module and a stack arrangement of semiconductor modules is proposed. The semiconductor module comprises an insulated gate bipolar transistor, a wide band-gap switch, a base plate, and a press device. The insulated gate bipolar transistor and the wide band-gap switch are connected in parallel and are each mounted with a first planar terminal to a side of the base plate. Further, a second planar terminal of the insulated gate bipolar transistor and a second planar terminal of the wind band-gap switch are connected with an electrically conductive connection element, and the press device is arranged on the second planar terminal of the insulated gate bipolar transistor. Hence, when arranging the semiconductor modules in a stack arrangement, any press force is primarily applied to the insulated gate bipolar transistors of the semiconductor modules.

A semiconductor device includes a semiconductor substrate, a transistor region, a diode region, a boundary trench gate, and a carrier control region. The boundary trench gate is provided in a boundary portion between the transistor region and the diode region.

The carrier control region is provided as a surface layer of the semiconductor substrate at a position closer to the boundary trench gate than the source layer located between the boundary trench gate and the trench gate. A concentration of first conductivity type impurities contained in the carrier control region is higher than a concentration of the first conductivity type impurities contained in the source layer or a concentration of second conductivity type impurities contained in the carrier control region is lower than a concentration of the second conductivity type impurities contained in the source layer.

To provide a semiconductor device having excellent conduction characteristics of a transistor portion and a diode portion. The semiconductor device having a transistor portion and a diode portion, the semiconductor device includes: a drift region of a first conductivity type provided on a semiconductor substrate, a first well region of a second conductivity type provided on an upper surface side of the semiconductor substrate, an anode region of the second conductivity provided on the upper surface side of the semiconductor substrate, in the diode portion, and a first high concentration region of a second conductivity type which is provided in contact with a first well region between the anode region and the first well region, and has a higher doping concentration than the anode region.

In an IGBT region of a semiconductor device, a barrier region is disposed above a drift layer, and a contact trench is disposed between adjacent gate trenches in a semiconductor substrate. A first electrode is embedded in the contact trench. A connecting region is disposed between a bottom surface of the contact trench and the barrier region, and is connected to the barrier region and the first electrode. Further, the emitter region and the contact region are arranged in a direction different from an arrangement direction of the gate trenches. Thus, the semiconductor device can be miniaturized.

Tunnel field effect transistors include a semiconductor substrate; a source region in the semiconductor substrate; a drain region in the semiconductor substrate; a channel region in the semiconductor substrate between the source region and the drain region; and a gate electrode on the semiconductor substrate above the channel region. The source region comprises a first region having a first conductivity type, a third region having a second conductivity type that is different from the first conductivity type, and a second region having an intrinsic conductivity type that is between the first region and the third region.

The present invention provides an efficient heat treatment such as activation treatment of impurities on a substrate such as a thick silicon wafer with large heat capacity by laser annealing.

Provided is a laser annealing apparatus 1 for heat-treating a surface of a substrate 30 comprising: a pulse oscillation laser source 10 which generates a pulse laser with gentle rise time and long pulse width; a continuous wave laser source 20 which generates a near-infrared laser for assisting annealing; optical systems 12, 22 which shape and guide beams 15, 25 of the two types of lasers respectively so as to irradiate the surface of the substrate 30 therewith; and a moving device 3 which moves the substrate 30 relatively to the laser beams 15, 25 to allow scanning of the combined irradiation of the two types of laser beams. According to this apparatus, deep activation of impurities can be performed in a thick semiconductor substrate with large heat capacity while securing sufficient light penetration depth and thermal diffusion length therefor.

A first region is formed by injecting a first condition type first dopant into a surface layer portion of an IGBT section of a semiconductor substrate. A second region is formed by injecting a second condition type second dopant into a region of the IGBT section shallower than the first region. An amorphous third region is formed by injecting the first conduction type third dopant into a surface layer portion of a diode section at a concentration higher than that of the second dopant. Thereafter, the IGBT section and the diode section are laser-annealed under conditions in which the third region is partially melted and the first dopant is activated. Subsequently, a surface layer portion which is shallower than the second injection region in the entire region of the IGBT section and the diode section is melted and crystallized by annealing the IGBT section and the diode section.

A gate controlled semiconductor device comprising a collector region of a first conductivity type; a drift region of a second conductivity type located over the collector region; a body region of a first conductivity type located over the drift region; at least one first contact region of a second conductivity type located above the body region and having a higher doping concentration compared to the body region. The device further comprises at least one second contact region of a first conductivity type located laterally adjacent to the at least one first contact region, the at least one second contact region having a higher doping concentration than the body region. The device further comprises at least one active trench extending from a surface into the drift region, in which the at least one first contact region adjoins the at least one active trench so that, in use, a channel region is formed along said at least one active trench and within the body region. The at least one active trench comprises: two vertical sidewalls and a bottom surface between the two vertical sidewalls; and an insulation layer along the vertical side walls and the bottom surface, wherein the insulation layer along at least one vertical side wall comprises different thicknesses; at least one auxiliary trench extending from the surface into the drift region. The at least one auxiliary trench comprises: two vertical sidewalls and a bottom surface between the two vertical sidewalls; and an insulation layer along the vertical side walls and the bottom surface, wherein the insulation layer along at least one vertical side wall comprises a constant thickness.

Method for manufacturing an insulated gate bipolar transistor, which includes a drift layer of a first conductivity type between an emitter side, at which a gate and emitter electrode are arranged, and a collector side, at which a collector electrode is arranged including steps: providing a substrate of a second conductivity type, applying a dopant of the first conductivity type on the first side, creating a drift layer of the first conductivity type on the first layer, diffusing the ions such that a buffer layer is created, having a higher doping concentration than the drift layer, creating a base layer of the second conductivity type on the drift layer, creating an emitter layer of the first conductivity type on the base layer, thinning the substrate on the second side such that the remaining part of the substrate forms a collector layer.