A semiconductor device includes an N+ type substrate, an N− type layer disposed on a first surface of the N+ type substrate and having a trench opened to a surface opposite to the surface facing the N+ type substrate, a P type region disposed in the N− type layer and disposed on a side surface of the trench, a gate electrode disposed in the trench, and a source electrode and a drain electrode insulated from the gate electrode. The N− type layer includes a P type shield region covering a bottom surface and an edge of the trench.

In accordance with a method of manufacturing CZ silicon wafers, a parameter of at least two of the CZ silicon wafers is measured. A group of the CZ silicon wafers falling within a tolerance of a target specification is determined. The group of the CZ silicon wafers is divided into sub-groups taking into account the measured parameter. An average value of the parameter of the CZ silicon wafers of each sub-group differs among the sub-groups, and a tolerance of the parameter of the CZ silicon wafers of each sub-group is smaller than a tolerance of the parameter of the target specification. A labeling configured to distinguish between the CZ silicon wafers of different sub-groups is prepared. The CZ silicon wafers falling within the tolerance of the target specification are packaged.

A semiconductor arrangement and method of manufacture is provided. In some embodiments, a semiconductor arrangement includes a collector region having a first surface coplanar with a first surface of a semiconductor layer, a drift region over a portion of the collector region and having a first surface coplanar with the first surface of the semiconductor layer, and a body region over the drift region. A body contact is in the body region. An emitter contact contacts the body contact and the body region. A collector contact contacts the first surface of the collector region. A first gate structure is adjacent the first surface of the drift region, the body region, and the body contact.

A semiconductor device includes: a semiconductor layer of a first conductivity-type; a well region of a second conductivity-type provided at an upper part of the semiconductor layer; a base region of the second conductivity-type provided at an upper part of the well region; a carrier supply region of the first conductivity-type provided at an upper part of the base region; a drift region of the first conductivity-type provided separately from the base region; a carrier reception region of the first conductivity-type provided at an upper part of the drift region; a gate electrode provided on a top surface of the well region interposed between the base region and the drift region via a gate insulating film; and a punch-through prevention region of the second conductivity-type provided at the upper part of the well region and having an impurity concentration different from the impurity concentration of the base region.

Embodiments of this application disclose a semiconductor device, a related chip, and a preparation method. The semiconductor device includes an N-type drift layer and an N-type field stop layer adjacent to the N-type drift layer. A density of free electrons at the N-type field stop layer is higher than a density of free electrons at the N-type drift layer. The N-type field stop layer includes first type impurity particles and second type impurity particles doped with the first type impurity particles, and a radius of the second type impurity particles is greater than a radius of the first type impurity particles. In the N-type field stop layer, an injection density of the first type impurity particles in a region adjacent to the N-type drift layer is higher than an injection density of the first type impurity particles in any other region.

Disclosed is a semiconductor structure including at least one bipolar junction transistor (BJT), which is uniquely configured so that fabrication of the BJT can be readily integrated with fabrication of complementary metal oxide semiconductor (CMOS) devices on an advanced silicon-on-insulator (SOI) wafer. The BJT has an emitter, a base, and a collector laid out horizontally across an insulator layer and physically separated. Extension regions extend laterally between the emitter and the base and between the base and the collector and are doped to provide junctions between the emitter and the base and between the base and the collector. Gate structures are on the extension regions. The emitter, base, and collector are contacted. Optionally, the gate structures and a substrate below the insulator layer are contacted and can be biased to optimize BJT performance. Optionally, the structure further includes one or more CMOS devices. Also disclosed is a method of forming the structure.

An SOI lateral homogenization field high voltage power semiconductor device, and a manufacturing method and application thereof are provided. The device includes a type I conductive semiconductor substrate, a type II conductive drift region, a type I field clamped layer, type I and type II conductive well regions, the first dielectric oxide layer forming a field oxide layer, the second dielectric oxide layer forming a gate oxide layer, a type II conductive buried dielectric layer, a type II conductive source heavily doped region, a type II conductive drain heavily doped region. The first dielectric oxide layer and the floating field plate polysilicon electrodes form a vertical floating field plate distributed throughout the type II conductive drift region to form a vertical floating equipotential field plate array. When the device is in on-state, high doping concentration can be realized by the full-region depletion effect form the vertical field plate arrays.

An apparatus includes a drift region formed over the substrate, a body region over the substrate, a first well region formed over the drift region, a collector region formed in the first well region, an emitter region formed in the body region, a first body contact formed in the body region, a first gate situated between the collector region and the emitter region, a second well region formed over the substrate, a drain region formed in the second well region, wherein the drain region and the emitter region are electrically connected to each other, a source region formed in the second well region, wherein the source region and the first body contact are electrically connected to each other, and a second gate situated between the drain region and the source region, wherein the second gate and the first gate are electrically connected to each other.

Disclosed is a semiconductor structure including at least one bipolar junction transistor (BJT), which is uniquely configured so that fabrication of the BJT can be readily integrated with fabrication of complementary metal oxide semiconductor (CMOS) devices on an advanced silicon-on-insulator (SOI) wafer. The BJT has an emitter, a base, and a collector laid out horizontally across an insulator layer and physically separated. Extension regions extend laterally between the emitter and the base and between the base and the collector and are doped to provide junctions between the emitter and the base and between the base and the collector. Gate structures are on the extension regions. The emitter, base, and collector are contacted. Optionally, the gate structures and a substrate below the insulator layer are contacted and can be biased to optimize BJT performance. Optionally, the structure further includes one or more CMOS devices. Also disclosed is a method of forming the structure.

In this patent application, a new Metal Oxide Semiconductor MOS planar cell design concept is proposed. The inventive power semiconductor includes a planar cell forming a horizontal channel and a plurality of trenches, which are arranged orthogonally to the plane of the planar cells. A second p base layer is introduced which extends perpendicularly deeper than the source region and laterally to the same distance/extent as the source region. Therefore, a vertical channel is prevented from forming in the trench regions while allowing the horizontal channels to form. This is extremely important in order to avoid significant issues (i.e. shifts in Vth) encountered in prior art IGBT designs. The new cell concept adopts planar MOS channel and Trench technology in a single MOS cell structure. The new design offers a wide range of advantages both in terms of performance (reduced losses, improved controllability and reliability), and processability (narrow mesa design rules, reliable planar process compatibility) and can be applied to both IGBTs and MOSFETs based on silicon or wide bandgap materials such as Silicon Carbide SiC. Furthermore, the device is easy to manufacture, because the inventive design can be manufactured based on a self-aligned process with minimum number of masks, with the potential of additionally applying enhancement layers and/or reverse conducting type of structures.