A semiconductor device includes a substrate having opposed first and second major surface, an active area, and a termination area. Insulated trenches extend from the first major surface toward the second major surface, each of the insulated trenches including a conductive field plate and a gate electrode overlying the conductive field plate, the gate electrode being separated from the field plate by a gate-field plate insulator. The field plate extends longitudinally in both of the active and termination areas and the gate electrode is absent in the termination area. A body region of a first conductivity type extends laterally between pairs of the insulated trenches. First and second spacer regions of a second conductivity type extend laterally between the pairs of the insulated trenches at the termination area to produce segments of the first conductivity type between the first and second spacer regions that are isolated from the body region.

A semiconductor device is provided. In an example, the semiconductor device includes a trench gate structure in a silicon carbide (SiC) semiconductor body. The semiconductor device includes a source region of a first conductivity type that adjoins the trench gate structure in a first segment. The semiconductor device includes a semiconductor region of a second conductivity type. The semiconductor region includes a first sub-region arranged below the source region in the first segment, and a second sub-region arranged in a second segment that adjoins the first segment. The semiconductor device includes a current spread region of the first conductivity type. The current spread region includes a first sub-region that adjoins the trench gate structure in the first segment at a vertical distance to a first surface of the SiC semiconductor body, and a second sub-region that is spaced from the trench gate structure in the second segment at the vertical distance to the first surface by a lateral distance.

A semiconductor device including: a semiconductor substrate having a first and a second side, and including a donor layer with a doping concentration profile in a depth direction from the first to the second side. The donor layer includes: a first peak, situated at a first distance from the first side of said substrate; a first region adjacent to the first peak and extending in the depth direction from the first peak toward the first side, a second peak in said doping concentration profile, situated at a second distance from the first side of said substrate. Said second distance is less than said first distance and greater than zero; and a second region adjacent to the second peak and extending in the depth direction from the second peak toward the first side of the substrate, which has a doping concentration which is substantially uniform.

A base layer has a low concentration peak at a position between a portion located at a same depth as a lower end portion of a gate electrode and a portion located at a same depth as an upper end portion of the gate electrode in a concentration profile of an impurity concentration in a depth direction. An impurity region has a boundary with the base layer in the depth direction at a position between a first peak position, at which the impurity concentration of the base layer is maximum between the portion located at the same depth as the lower end portion and the position of the low concentration peak, and a second peak position, at which the impurity concentration of the base layer is maximum between the position of the low concentration peak and the portion located at the same depth as the upper end portion.

Protection against electrostatic discharges is to be improved for electronic devices, or is to be provided in the first place. The device for protection against electrostatic discharges having an integrated semiconductor protection device comprises an inner region (1) configured at least as a thyristor (SCR) and at least one outer region (2a, 2b) configured as a corner region, which is formed and configured at least as a PNP transistor. The inner region (1) and the at least one outer region (2a, 2b) are arranged adjacent to one another.

The present application belongs to the technical field of semiconductor power devices and provides a semiconductor power device. The semiconductor power device includes an n-shaped substrate, an n-shaped epitaxial layer positioned on the n-shaped substrate, and at least three grooves recessed inside the n-shaped epitaxial layer, where a portion of the n-shaped epitaxial layer between two adjacent grooves of the at least three grooves is a mesa structure, an upper part of the mesa structure is provided with a p-shaped body region, and an n-shaped source region is provided inside the p-shaped body region. The mesa structure includes at least one mesa structure with a lower width being a first width and at least one mesa structure with a lower width being a second width, and the second width is greater than the first width.

An LDMOS transistor includes a P-type body region formed on a main surface of a semiconductor substrate, an N-type source region, an N-type drift region, an N-type drain region, a gate electrode formed via a gate insulating film, a first field plate formed on the drift region via a first insulating film, a plurality of second field plates being in contact with the source region or the gate electrode and formed on the first field plate via a second insulating film, a P-type first buried region, and a P-type second buried region having an impurity concentration lower than an impurity concentration of the first buried region. Distances of the first and second field plates from the drain region in the semiconductor substrate plane direction decrease toward the upper layers, and have a predetermined relationship with the distances between the first and second buried regions and the drain region.

A semiconductor device includes a deep well region located on a substrate, a drift region located in the deep well region, a first gate electrode that overlaps with the first body region and the drift region, a second gate electrode that overlaps with the second body region and the drift region, a first source region and a second source region located in the first and second body regions, respectively, a drain region located in the drift region and disposed between the first gate electrode and the second gate electrode, a silicide layer located on the substrate, a first non-silicide layer located between the drain region and the first gate electrode, wherein the first non-silicide layer extends over a top surface of the first gate electrode, and a first field plate contact plug in contact with the first non-silicide layer.

A semiconductor device includes: a semiconductor body having a first surface, a second surface opposite to the first surface in a vertical direction, an active region, and a sensor region arranged adjacent to the active region in a horizontal direction; transistor cells at least partly integrated in the active region, each transistor cell including a drift region separated from a source region by a body region, and a gate electrode dielectrically insulated from the body region; at least one sensor cell at least partly integrated in the sensor region, each sensor cell including a drift region separated from a source region by a body region, and a gate electrode dielectrically insulated from the body region; and an intermediate region arranged between the active region and the sensor region, the intermediate region including a drift region and an undoped semiconductor region extending from the first surface into the drift region.

A diode includes a semiconductor region having at least one two-dimensional carrier channel of a first conductivity type, the first conductivity type being one of a n-type and a p-type conductivity, the at least one two-dimensional channel having a net charge; a material of a second conductivity type, the second conductivity type being the other of the n-type and the p-type conductivity, disposed on the semiconductor region, the material of the second conductivity type having a net-charge in a depletion region that is substantially equal to the net-charge of the at least one two-dimensional channel in the semiconductor region when the diode is under reverse bias; an anode material in contact with at least a portion of the at least one two-dimensional channel and at least a portion of the material of the second conductivity type; and a cathode material in contact with the at least one two-dimensional carrier channel.