Disclosed are a superjunction semiconductor device and a method of manufacturing the same. More particularly, a superjunction semiconductor device and a method of manufacturing the same include an additional structure that enables smooth current flow in a transition region and/or a ring region of the device, where the current concentrates locally during turn-on/turn-off operations of the device due to insufficient current paths compared to the cell region of the device, thereby improving reverse recovery characteristics and preventing device destruction.

According to an embodiment of the invention, a semiconductor device includes a base body that includes silicon carbide, a first semiconductor member that includes silicon carbide and is of a first conductivity type, and a second semiconductor member that includes silicon carbide and is of a second conductivity type. A first direction from the base body toward the first semiconductor member is along a [0001] direction of the base body. The second semiconductor member includes a first region, a second region, and a third region. The first semiconductor member includes a fourth region. A second direction from the first region toward the second region is along a [1-100] direction of the base body. The fourth region is between the first region and the second region in the second direction. A third direction from the fourth region toward the third region is along a [11-20] direction of the base body.

A lateral double-diffused metal-oxide-semiconductor (LDMOS) transistor including a breakdown voltage clamp includes a drain n+ region, a source n+ region, a gate, and a p-type reduced surface field (PRSF) layer including one or more bridge portions. Each of the one or more bridge portions extends below the drain n+ region in a thickness direction. Another LDMOS transistor includes a drain n+ region, a source n+ region, a gate, an n-type reduced surface field (NRSF) layer disposed between the source n+ region and the drain n+ region in a lateral direction, a PRSF layer disposed below the NRSF layer in a thickness direction orthogonal to the lateral direction, and a p-type buried layer (PBL) disposed below the PRSF layer in the thickness direction. The drain n+ region is disposed over the PBL in the thickness direction.

A semiconductor device includes a semiconductor part; first and second electrodes, the semiconductor part being provided between the first and second electrodes; a control electrode selectively provided between the semiconductor part and the second electrode; and a contacting part electrically connecting the semiconductor part and the second electrode. The semiconductor part includes a first layer of a first conductivity type, a second layer of a second conductivity type provided between the first layer and the second electrode, a third layer of the first conductivity type selectively provided between the second layer and the second electrode, and a fourth layer of the second conductivity type selectively provided between the second layer and the second electrode. The contacting part includes a first semiconductor portion of the first conductivity type contacting the third layer, and a second semiconductor portion of the second conductivity type contacting the fourth layer.

This application provides an insulated gate bipolar transistor, a motor control unit, and a vehicle. The insulated gate bipolar transistor includes three device structure feature layers that are laminated. An IGBT device structure feature layer (10) and an RC-IGBT device structure feature layer (30) are respectively arranged on two sides of an SJ device structure feature layer (20). The RC-IGBT device structure feature layer (30) includes a collector (12) and a drain (13) that are disposed at a same layer. The insulated gate bipolar transistor further includes a first metal electrode (15) laminated with and electrically connected to the collector (12), and a second metal electrode (14) laminated with and electrically connected to the drain (13), and the first metal electrode (15) is electrically isolated from the second metal electrode (14).

A method of operating a beamline ion implanter may include performing, in an ion implanter, a first implant procedure to implant a dopant of a first polarity into a given semiconductor substrate, and generating an estimated implant dose of the dopant of the first polarity based upon a set of filtered information, generated by the first implant procedure. The method may also include calculating an actual implant dose of the dopant of the first polarity using a predictive model based upon the estimated implant dose, and performing, in the ion implanter, an adjusted second implant procedure to implant a dopant of a second polarity into a select semiconductor substrate, based upon the actual implant dose.

A semiconductor device of the present invention includes a semiconductor region having a first main surface, wherein the semiconductor region includes: alternating n-type pillar layers and p-type pillar layers along the first main surface; a p-type first well layer located within each of the n-type pillar layers at a top surface of the n-type pillar layer; an n-type first source layer located within the first well layer at a top surface of the first well layer; a first side surface dielectric layer located on a side surface in a first trench located at each of boundaries between the n-type pillar layers and the p-type pillar layers, and being in contact with the first well layer and the first source layer; a first bottom surface dielectric layer located on a bottom surface in the first trench, and being at least partially in contact with one of the p-type pillar layers.

A pillar structure includes an epitaxial layer of a first conductivity type including an active region and a peripheral region surrounding the active region and a plurality of pillars of a second conductivity type, the pillars extending in a vertical direction within the epitaxial layer, being spaced apart from each other in a horizontal direction, respectively, and including active pillars provided in the active region and peripheral pillars provided in the peripheral region, wherein the active pillars are spaced apart from another adjacent each other at a first pitch, and a pair of the peripheral pillars are branched from one of the active pillars and are spaced apart from each other at a second pitch smaller than the first pitch.

Disclosed are a superjunction semiconductor device and a method of manufacturing the same. More particularly, the superjunction semiconductor device includes at least one body region in a second corner region extending along the length direction in the same manner as a pillar, thereby promoting smooth current flow in a transition corner region and thus improving reverse recovery characteristics; and a method of manufacturing the superjunction semiconductor device.

A power semiconductor device includes an SiC semiconductor layer, a plurality of well regions disposed in the semiconductor layer such that two adjacent well regions at least partially make contact with each other, a plurality of source regions on the plurality of well regions in the semiconductor layer, a drift region in a first conductive type, a plurality of trenches recessed into the semiconductor layer from the surface of the semiconductor layer, a gate insulating layer on an inner wall of each trench, a gate electrode layer disposed on the gate insulating layer and including a first part disposed in each trench and a second part on the semiconductor layer, and a pillar region positioned under the plurality of well regions to make contact with the drift region and the plurality of well regions in the semiconductor layer, and having a second conductive type.