A semiconductor device has an active region through which a main current flows, a gate ring region surrounding a periphery of the active region, a source ring region surrounding a periphery of the gate ring region, and a termination region surrounding a periphery of the source ring region. The semiconductor device has a semiconductor substrate of a first conductivity type, a first semiconductor layer of the first conductivity type, a second semiconductor layer of a second conductivity type, and further, in the active region, first semiconductor regions of the first conductivity type, a gate insulating film, first gate electrodes, an interlayer insulating film, a first first-electrode, a first plating film, and a second electrode. The semiconductor device has, in the source ring region, a second first-electrode provided at a surface of the second semiconductor layer, and a second plating film provided on the second first-electrode.

A super junction MOSFET device, including: a substrate having a first conductive type; a buffer layer having the first conductive type and disposed on the substrate; a super junction structure disposed on the buffer layer and including multiple first conductive type pillars and multiple second conductive type pillars alternately arranged in a transverse direction, several second conductive type pillars being partially and/or wholly displaced to provide two or more different transverse dimensions for the first conductive type pillars; a body region having the second conductive type and disposed on a top of the second conductive type pillar; a source structure located within the body region and including a source region having the first conductive type and an ohmic contact region having the second conductive type which contacts with the source region; and a gate structure in contact with the first conductive type pillar and the source structure.

A semiconductor device is disclosed. The device includes an epitaxial layer on a substrate, wherein the epitaxial layer includes first trenches and second trenches alternately arranged along a first direction. The epitaxial layer between the adjacent first and second trenches includes a first doping region and a second doping region, and the first doping region and the second doping region have different conductivity types. An interface is between the first doping region and the second doping region to form a super-junction structure. A gate structure is on the epitaxial layer. The epitaxial layer under the gate structure includes a channel extending along a second direction, and the first direction is perpendicular to the second direction.

According to an embodiment, a semiconductor device is provided. The device includes: The second region has a greater curvature than the first region. The device includes: an N-type epitaxy layer; a P-well in the N-type epitaxy layer; a drain in the N-type epitaxy layer; a source in the P-well; and a bulk in the P-well and in contact with the source, wherein the bulk has a greater area in the second region than in the first region.

A semiconductor substrate is provided with a first cell region, the first cell region including: an n-type emitter region; a p-type first top body region; an n-type first barrier region; an n-type first pillar region; and a p-type first bottom body region, the semiconductor substrate may further comprise: an n-type drift region; a p-type collector region; an n-type cathode region, the n-type first barrier region may include a first peak position where a peak of the n-type impurity density is present within a part linked to the n-type first pillar region, and a second peak position where a peak of the n-type impurity density is present within a part in contact with the gate insulating layer, and a depth of the first peak position from a front surface of the semiconductor substrate is different from a depth of the second peak position from the front surface of the semiconductor substrate.

In a field-effect semiconductor device, alternating first n-type and p-type pillar regions are arranged in the active area. The first n-type pillar regions are in Ohmic contact with the drain metallization. The first p-type pillar regions are in Ohmic contact with the source metallization. An integrated dopant concentration of the first n-type pillar regions substantially matches that of the first p-type pillar regions. A second p-type pillar region is in Ohmic contact with the source metallization, arranged in the peripheral area and has an integrated dopant concentration smaller than that of the first p-type pillar regions divided by a number of the first p-type pillar regions. A second n-type pillar region is arranged between the second p-type pillar region and the first p-type pillar regions, and has an integrated dopant concentration smaller than that of the first n-type pillar regions divided by a number of the first n-type pillar regions.

A method of manufacturing a semiconductor device includes forming a frame trench extending from a first surface into a base substrate, forming, in the frame trench, an edge termination structure comprising a glass structure, forming a conductive layer on the semiconductor substrate and the edge termination structure, and removing a portion of the conductive layer above the edge termination structure. A remnant portion of the conductive layer forms a conductive structure that covers a portion of the edge termination structure directly adjoining a sidewall of the frame trench.

A power semiconductor device includes a substrate, a main body, and an electrode unit. The main body includes an active portion disposed on the substrate, an edge termination portion, and an insulating layer disposed on the edge termination portion. The edge termination portion includes first-type semiconductor region, a second-type semiconductor region and a top surface. The first-type semiconductor region is adjacent to the active portion and has a first-type doping concentration decreased from the top surface toward the substrate. The electrode unit includes a first electrode disposed on the insulating layer, and a second electrode disposed on the substrate.

A semiconductor device which solves the following problem of a super junction structure: due to a relatively high concentration in the body cell region (active region), in peripheral areas (peripheral regions or junction end regions), it is difficult to achieve a breakdown voltage equivalent to or higher than in the cell region through a conventional junction edge terminal structure or resurf structure. The semiconductor device includes a power MOSFET having a super junction structure formed in the cell region by a trench fill technique. Also, super junction structures having orientations parallel to the sides of the cell region are provided in a drift region around the cell region.

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.