An SBD includes: a terminal well region formed to surround an active region; a field insulating film formed to cover part of the terminal well region; a surface electrode formed on a drift layer on an inner side in relation to the field insulating film and electrically connected to the terminal well region; a surface protection film covering an end portion on an outer side of the surface electrode; and a back surface electrode formed on a back surface of a single crystal substrate. An end portion of an outer side of the surface electrode in the corner portion of the terminal region is located on an inner side in relation to the end portion of the outer side of the surface electrode in a straight portion of a terminal region based on a position of an end portion of an outer side of the terminal well region.

A package structure including a first redistribution circuit structure, a semiconductor die, first antennas and second antennas is provided. The semiconductor die is located on and electrically connected to the first redistribution circuit structure. The first antennas and the second antennas are located over the first redistribution circuit structure and electrically connected to the semiconductor die through the first redistribution circuit structure. A first group of the first antennas are located at a first position, a first group of the second antennas are located at a second position, and the first position is different from the second position in a stacking direction of the first redistribution circuit structure and the semiconductor die.

A chip structure includes a substrate, a bottom conductive layer, a semiconductor layer, an interlayer dielectric layer, at least one electrode, and at least one top electrode. The substrate includes in order a core layer and a composite material. The bottom conductive layer is disposed on the bottom surface of the core layer, the semiconductor layer is disposed on the substrate, and an interlayer dielectric layer is disposed on the semiconductor layer. The at least one electrode is disposed between the semiconductor layer and the interlayer dielectric layer, and the at least one top electrode is disposed on the interlayer dielectric layer and electrically coupled to the at least one electrode.

Even in a case where a pad becomes smaller, solder connection strength is improved. A semiconductor device includes a pad, a diffusion layer, and a melting layer. The pad included by the semiconductor device includes a concave portion on a surface at which solder connection is to be performed. The diffusion layer included by the semiconductor device is disposed at the concave portion and constituted with a metal which remains on the surface of the pad while diffusing into solder upon the solder connection. The melting layer included by the semiconductor device is disposed adjacent to the diffusion layer and constituted with a metal which diffuses and melts into the solder upon the solder connection.

A semiconductor arrangement in fan out packaging has a molding compound adjacent a side of a semiconductor die. A magnetic structure is disposed above the molding compound, above the semiconductor die, and around a transmission line coupled to an integrated circuit of the semiconductor die. The magnetic structure has a top magnetic portion, a bottom magnetic portion, a first side magnetic portion, and a second side magnetic portion. The first side magnetic portion and the second side magnetic portion are coupled to the top magnetic portion and to the bottom magnetic portion. The first side magnetic portion and the second side magnetic portion have tapered sidewalls.

A semiconductor device includes: an N.sup.− drift layer of a first conductivity type formed in the semiconductor substrate; a P base layer formed on the N.sup.− drift layer; and an N buffer layer of the first conductivity type formed under the N.sup.− drift layer and higher in peak impurity concentration than the N.sup.− drift layer. The N buffer layer includes: a first buffer layer in which a trap level derived from lattice defect is not detected by a photoluminescence method; and a second buffer layer provided between the first buffer layer and the N.sup.− drift layer and in which two types of trap levels derived from lattice defect are detected by the photoluminescence method.

A power semiconductor device includes a semiconductor layer structure and a protective overcoating on a bonding surface of the semiconductor layer structure. The bonding surface includes a plurality of adhesion features along an interface with the protective overcoating. The adhesion features protrude from and/or are recessed in the bonding surface, and define an adhesion strength between the bonding surface and the protective overcoating that spatially varies along the interface. Related devices and fabrication methods are also discussed.

A power module package is provided. The power module package may include: a first substrate; a second substrate; a semiconductor chip disposed between the first substrate and the second substrate; and a mutual-connection layer that is formed between the semiconductor chip and the second substrate and provides conductive connection between the semiconductor chip and the second substrate.

The present disclosure relates to an integrated circuit. The integrated circuit includes a plurality of interconnects within a dielectric structure over a substrate. A passivation structure is arranged over the dielectric structure. The passivation structure has sidewalls connected to one or more upper surfaces of the passivation structure. A bond pad is arranged directly between the sidewalls of the passivation structure. An upper passivation layer is disposed over the passivation structure and the bond pad. The upper passivation layer extends from over an upper surface of the bond pad to within a recess in the upper surface of the bond pad.

A semiconductor package includes a first chip, a plurality of through vias and an encapsulant. The first chip has a first via and a protection layer thereon. The first via is disposed in the protection layer. The through vias are disposed aside the first chip. The encapsulant encapsulates the first chip and the plurality of through vias. A surface of the encapsulant is substantially coplanar with surfaces of the protection layer and the plurality of through vias.