A Schottky device includes a barrier height adjustment layer in a portion of a semiconductor material. In accordance with an embodiment, the Schottky device is formed from a semiconductor material of a first conductivity type which has a barrier height adjustment layer of a second conductivity type that extends from a first major surface of the semiconductor material into the semiconductor material a distance that is less than a zero bias depletion boundary. A Schottky contact is formed in contact with the doped layer.

A diode includes a semiconductor substrate having a surface; a first contact region disposed at the surface of the semiconductor substrate and having a first conductivity type; and a second contact region disposed at the surface, laterally spaced from the first contact region, and having a second conductivity type. The diode also includes a buried region disposed in the semiconductor substrate vertically adjacent to the first contact region, having the second conductivity type, and electrically connected with the second contact region; and an isolation region disposed at the surface between the first and second contact regions. The diode also includes a separation region disposed at the surface between the first contact region and the isolation region, the separation region formed from a portion of a first well region disposed in the semiconductor substrate that extends to the surface.

An electric assembly includes a semiconductor switching device with a maximum breakdown voltage rating across two load terminals in an off-state. A clamping diode is electrically connected to the two load terminals and parallel to the switching device. A semiconductor body of the clamping diode is made of silicon carbide. An avalanche voltage of the clamping diode is lower than the maximum breakdown voltage rating of the switching device.

A superjunction bipolar transistor includes an active transistor cell area that includes active transistor cells electrically connected to a first load electrode at a front side of a semiconductor body. A superjunction area overlaps the active transistor cell area and includes a low-resistive region and a reservoir region outside of the low-resistive region. The low-resistive region includes a first superjunction structure with a first vertical extension with respect to a first surface of the semiconductor body. The reservoir region includes no superjunction structure or a second superjunction structure with a mean second vertical extension smaller than the first vertical extension.

A semiconductor device, in which, in a density distribution of first conductivity type impurities in the first conductivity type region measured along a thickness direction of the semiconductor substrate, a local maximum value N1, a local minimum value N2, a local maximum value N3, and a density N4 are formed in this order from front surface side, a relationship of N1>N3>N2>N4 is satisfied, a relationship of N3/10>N2 is satisfied, and a distance a from the surface to the depth having the local maximum value N1 is larger than twice a distance b from the depth having the local maximum value N1 to the depth having the local minimum N2.

A method for forming a semiconductor device includes implanting doping ions into a semiconductor substrate. A deviation between a main direction of a doping ion beam implanting the doping ions and a main crystal direction of the semiconductor substrate is less than 0.5 during the implanting of the doping ions into the semiconductor substrate. The method further includes controlling a temperature of the semiconductor substrate during the implantation of the doping ions so that the temperature of the semiconductor substrate is within a target temperature range for more than 70% of an implant process time used for implanting the doping ions. The target temperature range reaches from a lower target temperature limit to an upper target temperature limit. The lower target temperature limit is equal to a target temperature minus 30 C., and the target temperature is higher than 80 C.

Three-dimensional electrostatic discharge (ESD) semiconductor devices are fabricated together with three-dimensional non-ESD semiconductor devices. For example, an ESD diode and FinFET are fabricated on the same bulk semiconductor substrate. A spacer merger technique is used in the ESD portion of a substrate to create double-width fins on which the ESD devices can be made larger to handle more current.

A semiconductor device for restraining snapback is provided. The semiconductor device includes IGBT and diode regions. In a view of n-type impurity concentration distribution along a direction from a front surface to a rear surface, a local minimum value of an n-type impurity concentration is located at a border between cathode and buffer regions. A local maximum value of n-type impurity concentration is located in the buffer region. At least one of the buffer and cathode regions includes a crystal defect region having crystal defects in a higher concentration than a region therearound. A peak of a crystal defect concentration in a view of crystal defect concentration distribution along the direction from the front surface to the rear surface is located in a region on the rear surface side with respect to a specific position having the n-type impurity concentration which is a half of the local maximum value.

A power semiconductor device includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type, a pair of conductive bodies, a third semiconductor layer of the second conductivity type, and a fourth semiconductor layer of the first conductivity type. The second semiconductor layer is provided on the first semiconductor layer on the first surface side. The pair of conductive bodies are provided via an insulating film in a pair of first trenches extending across the second semiconductor layer from a surface of the second semiconductor layer to the first semiconductor layer. The third semiconductor layer is selectively formed on the surface of the second semiconductor layer between the pair of conductive bodies and has a higher second conductivity type impurity concentration in a surface of the third semiconductor layer than the second semiconductor layer.

This invention discloses a semiconductor power device formed in a semiconductor substrate includes rows of multiple horizontal columns of thin layers of alternate conductivity types in a drift region of the semiconductor substrate where each of the thin layers having a thickness to enable a punch through the thin layers when the semiconductor power device is turned on. In a specific embodiment the thickness of the thin layers satisfying charge balance equation q*N.sub.D*W.sub.N=q*N.sub.A*W.sub.P and a punch through condition of W.sub.P<2*W.sub.D*[N.sub.D/(N.sub.A+N.sub.D)] where N.sub.D and W.sub.N represent the doping concentration and the thickness of the N type layers 160, while N.sub.A and W.sub.P represent the doping concentration and thickness of the P type layers; W.sub.D represents the depletion width; and q represents an electron charge, which cancel out. This device allows for a near ideal rectangular electric field profile at breakdown voltage with sawtooth like ridges.