A highly reliable semiconductor device with high withstand voltage is provided. As means therefor, an impurity concentration in a first JTE region is set to 4.410.sup.17 cm.sup.3 or higher and 610.sup.17 cm.sup.3 or lower and an impurity concentration in a second JTE region is set to 210.sup.17 cm.sup.3 or lower in a case of a Schottky diode, and an impurity concentration in the first JTE region is set to 610.sup.17 cm.sup.3 or higher and 810.sup.17 cm.sup.3 or lower and an impurity concentration in the second JTE region is set to 210.sup.17 cm.sup.3 or lower in a case of a junction barrier Schottky diode.

An OTP (One-Time Programmable) memory including OTP memory cells that utilize OTP elements fabricated in CMOS FinFET processes. The OTP memory cell can also include at least one selector built upon at least one fin structure that has at least one CMOS gate to divide the fin structure into at least a first and a second active region. The selector can be implemented as a MOS device, dummy-gate diode, or Schottky diode as selector such as by using different types of source/drain implants. The OTP element that can be implemented as polysilicon, silicided polysilicon, CMOS metal gate, any layers of metal as interconnect, or active region. In one embodiment, the OTP element can be a fin structure and can be built upon the same fin structure as the at least one of the selector. By using different source/drain implant schemes on the two active regions, the selector can be turned on as MOS device, MOS device and/or diode, dummy-gate diode, or Schottky diode.

According to a first aspect of the present invention, a method of manufacturing semiconductor device includes the step of preparing a silicon substrate. The silicon substrate includes an N-type silicon layer on one surface and at least one of a PN junction, an electrode film, and a protective film on another surface. The method includes the steps of forming a SiTi junction by forming a first electrode film made of titanium on the N-type silicon layer; forming a second electrode film made of AlSi on the first electrode film; forming a third electrode film made of Ni on the second electrode film; and heating the silicon substrate after forming the third electrode film. A titanium silicide layer is not formed between the N-type silicon layer and the first electrode film.

A Magnetic Czochralski semiconductor wafer having opposing first and second sides arranged distant from one another in a first vertical direction is treated by implanting first particles into the semiconductor wafer via the second side to form crystal defects in the semiconductor wafer. The crystal defects have a maximum defect concentration at a first depth. The semiconductor wafer is heated in a first thermal process to form radiation induced donors. Implantation energy and dose are chosen such that the semiconductor wafer has, after the first thermal process, an n-doped semiconductor region arranged between the second side and first depth, and the n-doped semiconductor region has, in the first vertical direction, a local maximum of a net doping concentration between the first depth and second side and a local minimum of the net doping concentration between the first depth and first maximum.

A semiconductor device comprises a vertical power device, such as a superjunction MOSFET, an IGBT, a diode, and the like, and a surface device that comprises one or more lateral devices that are electrically active along a top surface of the semiconductor device.

An element isolation trench is formed in a substrate and is formed along each side of a polygon in a planar view. A first trench is formed in the substrate and extends in a direction different from that of any side of the trench. A first-conductivity type region is formed on/over apart located on the side of an end of the first trench in the substrate. Accordingly, when an impurity region that extends in a depth direction in the substrate is formed by forming the trench in the substrate and diagonally implanting an impurity into the trench, the impurity is prevented from being implanted into a side face of a groove such as a groove for element isolation and so forth impurity implantation into the side face of which is not desired.

A chip part includes a substrate, an element formed on the substrate, and an electrode formed on the substrate. A recess and/or projection expressing information related to the element is formed at a peripheral edge portion of the substrate.

A semiconductor device includes a semiconductor substrate and a pair of first well regions formed in the semiconductor substrate, wherein the pair of first well regions have a first conductivity type and are separated by at least one portion of the semiconductor substrate. The semiconductor device also includes a first doping region formed in a portion of at least one portion of the semiconductor substrate separating the pair of first well regions, and a pair of second doping regions, respectively formed in one of the pair of first well regions, having the first conductivity type. Further, the semiconductor device includes a pair of insulating layers, respectively formed over a portion of the semiconductor substrate to cover a portion of the first doped region and one of the pair of second doping regions.

A semiconductor device includes a substrate and a p-doped layer including a doped III-V material on the substrate. An n-type layer is formed on or in the p-doped layer. The n-type layer includes ZnO on the p-doped layer to form an electronic device.

A semiconductor device manufacturing method according to an embodiment includes: forming an n-type SiC layer on a SiC substrate; forming a p-type impurity region at one side of the SiC layer; exposing other side of the SiC layer by removing at least part of the SiC substrate; implanting carbon (C) ions into exposed part of the SiC layer; performing a heat treatment; forming a first electrode on the p-type impurity region; and forming a second electrode on the exposed part of the SiC layer.