A semiconductor device includes a first conductive type semiconductor layer which has a principal surface, a second conductive type well region which demarcates an active region and an outer region on the principal surface and is formed on a surface layer portion of the principal surface and includes a high concentration portion high in impurity concentration on the active region side and includes a low concentration portion lower in impurity concentration than the high concentration portion on the outer region side, and a second conductive type impurity region of the active region which is formed on a surface layer portion of the principal surface.

High voltage semiconductor devices are described herein. An exemplary semiconductor device includes a first doped region and a second doped region disposed in a substrate. The first doped region and the second doped region are oppositely doped and adjacently disposed in the substrate. A first isolation structure and a second isolation structure are disposed over the substrate, such that each are disposed at least partially over the first doped region. The first isolation structure is spaced apart from the second isolation structure. A resistor is disposed over a portion of the first isolation structure and electrically coupled to the first doped region. A field plate disposed over a portion of the second doped region and electrically coupled to the second doped region.

A method of forming a power semiconductor device includes providing a semiconductor layer of a first conductivity type extending to a first side and having a first doping concentration of first dopants providing majority charge carriers of a first electric charge type in the layer, and forming a deep trench isolation including forming a trench which extends from the first side into the semiconductor layer and includes, in a vertical cross-section perpendicular to the first side, a wall, forming a compensation semiconductor region of the first conductivity type at the wall and having a second doping concentration of the first dopants higher than the first doping concentration, and filling the trench with a dielectric material. The amount of first dopants in the compensation semiconductor region is such that a field-effect of fixed charges of the first electric charge type which are trapped in the trench is at least partly compensated.

A composite power element includes a substrate structure, an insulation layer, a dielectric layer, a MOSFET, and a Zener diode. The MOSFET is formed in a transistor formation region of the substrate structure. The Zener diode is formed in a circuit element formation region of the substrate structure, and includes a Zener diode doping structure that is formed in the substrate structure and is covered by the insulation layer. The Zener diode doping structure includes a first P-type doped region and a first N-type doped region that is formed on an inner side of the first P-type doped region. The Zener diode further includes a Zener diode metal structure that is formed on the dielectric layer and sequentially passes through the dielectric layer and the insulation layer to be electrically connected to the first P-type doped region and the first N-type doped region.

Semiconductor devices, and more particularly semiconductor devices with improved edge termination structures are disclosed. A semiconductor device includes a drift region that forms part of an active region. An edge termination region is arranged along a perimeter of the active region and also includes a portion of the drift region. The edge termination region includes one or more sub-regions of an opposite doping type than the drift region and one or more electrodes may be capacitively coupled to the drift region by way of the one or more sub-regions. During a forward blocking mode for the semiconductor device, the one or more electrodes may provide a path that draws ions away from passivation layers that are on the edge termination region and away from the active region. In this manner, the semiconductor device may exhibit reduced leakage, particularly at higher operating voltages and higher associated operating temperatures.

A method for manufacturing a power semiconductor device includes: forming a drift region of a first conductivity type, a second emitter region of a second conductivity type, a pn-junction between the second emitter region and drift region, and a first emitter region having a first doping region of the first conductivity type and a second doping region of the first conductivity type; forming a first emitter metallization in contact with the first emitter region to form an ohmic contact between the first emitter metallization and the first doping region, and to form a non-ohmic contact between the first emitter metallization and the second doping region; and forming a second emitter metallization in contact with the second emitter region. The first emitter region is formed using a mask that is aligned with respect to the second emitter region, so that the first and second doping regions are formed in aligned relation.

A semiconductor integrated circuit device having a first clamping circuit, a second clamping circuit, a third clamping circuit, a first path-changing line and a second path-changing line. The first clamping circuit may be connected between an input/output pad and a power pad. The first clamping circuit may include a plurality of diodes serially connected with each other. The second clamping circuit may be connected between the input/output pad and a ground pad. The second clamping circuit may include a plurality of diodes serially connected with each other. The third clamping circuit may be connected between the power pad and the ground pad. The third clamping circuit may include a plurality of diodes serially connected with each other. First and second path-changing lines may be configured to direct static electricity paths.

A high-speed diode includes an n-type semiconductor layer and a p-type semiconductor layer which is laminated on the n-type semiconductor layer, where a pn junction is formed in a boundary portion between the n-type semiconductor layer and the p-type semiconductor layer, and crystal defects are formed such that the frequency of appearance is gradually decreased from the upper surface of the p-type semiconductor layer toward the bottom surface of the n-type semiconductor layer.

The semiconductor device of the present invention includes a semiconductor substrate, a switching element which is defined on the semiconductor substrate, and a temperature sense element which is provided on the surface of the semiconductor substrate independently from the switching element and characterized by being dependent on a temperature.

An ESD protection device includes a semiconductor body having an upper surface, a plurality of p-type wells that each extend from the upper surface into the semiconductor body, a plurality of n-type wells that each extend from the upper surface into the semiconductor body, first isolation regions comprising an electrical insulator that laterally surrounds the p-type wells and extends from the upper surface into the semiconductor body at least as deep as the p-type wells, and second isolation regions comprising an electrical insulator that laterally surrounds the n-type wells and extends from the upper surface into the semiconductor body at least as deep as the n-type wells, wherein the p-type wells and the n-type wells alternate with one another a first direction, and wherein an isolating area of the first isolation regions is greater than an isolating area of the second isolation regions.