A semiconductor device includes a transistor cell area with active transistor cells including source zones electrically connected to a first load electrode. The source zones have a first conductivity type. An edge area surrounds the active transistor cell area and includes an edge construction that includes straight sections and a corner section connecting neighboring straight sections. A second dopant ratio between a mean concentration of dopants of a complementary second conductivity type and a mean concentration of dopants of the first conductivity type in the corner section exceeds a first dopant ratio between a mean concentration of dopants of the second conductivity type and a mean concentration of dopants of the first conductivity type in the straight sections by at least 0.2% in relation to the first dopant ratio.

To provide an optimal structure for electrically connecting an MOSFET region, a FWD region, and an IGBT region in parallel within one semiconductor chip by mitigating electric field concentration between a SJ column and a drift region, a semiconductor device is provided, the semiconductor device including: a semiconductor substrate: a super junction MOSFET having a repetitive structure of a first column and a second column; a parallel device having a drift region including second conductivity-type impurities, and being provided separately from the super junction MOSFET in the semiconductor substrate; and a boundary portion located between the super junction MOSFET and the parallel device in the semiconductor substrate, wherein the boundary portion extends from one main surface side to the other main surface side, and has at least one third column having first conductivity-type impurities, and the third column is shallower than the first column and the second column.

Semiconductor devices are formed using a thin epitaxial layer (nanotube) formed on sidewalls of dielectric-filled trenches. In one embodiment, a method for forming a semiconductor device includes forming a first epitaxial layer on sidewalls of trenches and forming second epitaxial layer on the first epitaxial layer where charges in the doped regions along the sidewalls of the first and second trenches achieve charge balance in operation. In another embodiment, the semiconductor device includes a termination structure including an array of termination cells.

According to one embodiment, a semiconductor device includes a plurality of first semiconductor regions of a first conductivity type, a plurality of second semiconductor regions of a second conductivity type, a third semiconductor region of the second conductivity type, a fourth semiconductor region of the second conductivity type, a fifth semiconductor region of the first conductivity type, and a gate electrode. An impurity concentration of the second conductivity type of the third semiconductor region is higher than an impurity concentration of the second conductivity type of the second semiconductor regions. The fourth semiconductor region is provided on the first semiconductor regions. The gate electrode provided on the fourth semiconductor region with a gate insulation layer interposed. The gate electrode extends in a third direction. The third direction intersects the first direction. The third direction is parallel to a plane including the first direction and the second direction.

A semiconductor device comprises at least one strip-shaped cell compensation region of a vertical electrical element arrangement, at least one strip-shaped edge compensation region and a bridge structure. The at least one strip-shaped cell compensation regions extends into a semiconductor substrate and comprises a first conductivity type. Further, the at least one strip-shaped cell compensation region is connected to a first electrode structure of the vertical electrical element arrangement. The at least one strip-shaped edge compensation region extends into the semiconductor substrate within an edge termination region of the semiconductor device and outside the cell region. Further, the at least one strip-shaped edge compensation region comprises the first conductivity type. The bridge structure electrically connects the at least one strip-shaped edge compensation region with the at least one strip-shaped cell compensation region within the edge termination region.

A super-junction semiconductor device includes a junction termination area at a first surface of a semiconductor body and at least partly surrounding an active cell area. An inner part of the junction termination area is arranged between an outer part of the junction termination area and the active cell area. A charge compensation device structure includes first regions of a first conductivity type and second regions of a second conductivity type disposed alternately along a first lateral direction. First surface areas correspond to a projection of the first regions onto the first surface, and second surface areas correspond to a projection of the second regions onto the first surface. The super-junction semiconductor device further includes at least one of a first junction termination extension structure and a second junction termination extension structure.

A charge-balanced (CB) diode may include one or more CB layers. Each CB layer may include an epitaxial layer having a first conductivity type and a plurality of buried regions having a second conductivity type. Additionally, the CB diode may include an upper epitaxial layer having the first conductivity type that is disposed adjacent to an uppermost CB layer of the one or more CB layers. The upper epitaxial layer may also include a plurality of junction barrier (JBS) implanted regions having the second conductivity type. Further, the CB diode may include a Schottky contact disposed adjacent to the upper epitaxial layer and the plurality of JBS implanted regions.

Complementary high-voltage bipolar transistors in silicon-on-insulator (SOl) integrated circuits is disclosed. In one disclosed embodiment, a collector region is formed in an epitaxial silicon layer disposed over a buried insulator layer. A base region and an emitter are disposed over the collector region. An n-type region is formed under the buried insulator layer (BOX) by implanting donor impurity through the active region of substrate and BOX into a p-substrate. Later in the process flow this n-type region is connected from the top by doped poly-silicon plug and is biased at Vcc. In this case it will deplete lateral portion of PNP collector region and hence, will increase its BV.

A power metal-oxide semiconductor field-effect transistor (MOSFET) and method of manufacturing thereof, includes a trench, a trench doping and a pillar doping region. The trench is etched into a silicon layer that includes a gate structure disposed therein. The trench doping is implanted in the silicon layer vertically below the trench and has an opposite doping type than the silicon layer. The pillar doping region is implanted in the silicon layer vertically below, and spaced from the trench doping. The pillar doping region has a same doping type as the trench doping.

A semiconductor arrangement is produced by providing a semiconductor carrier of a second conduction type and epitaxially growing a first semiconductor zone of a first conduction type on the carrier. The first semiconductor zone includes a semiconductor base material doped with first and second dopants which are made of different substances which are both different from the semiconductor base material. The first dopant is electrically active and causes a doping of the first conduction type in the semiconductor base material, and causes a decrease or an increase of a lattice constant of the first semiconductor zone. The second dopant causes one or both of hardening of the first semiconductor zone and an increase of the lattice constant of the first semiconductor zone if the first dopant causes a decrease, or a decrease of the lattice constant of the first semiconductor zone if the first dopant causes an increase.