To prevent cracks of an interlayer insulation film at the time of wire bonding while maintaining adhesion of an aluminum pad electrode and the interlayer insulation film in a semiconductor device in which the aluminum pad electrode and a lead frame are connected with bonding wire by a ball bonding technology. In a bonding pad that is configured to have multiple pad electrodes each with two or more layers, the pad electrodes being electrically connected with one another through vias, the vias are not arranged under an area to which a capillary end of a wire bonder contacts at the time of the wire bonding.

A reliability prediction method includes: calculating a change of each of a plurality of alloy phases at a bonding portion between an electrode pad and a bonding wire; setting a generation of a metal oxide phase caused by a corrosion reaction, based on an initial crack structure of the bonding portion; calculating an elastic strain energy at each of specified portions of the bonding portion; setting a progress of a crack, based on the elastic strain energy at each of the specified portions; and predicting a lifetime of the semiconductor device, based on a length of the crack due to the progress of the crack.

An integrated circuit device includes a wiring structure, first and second inter-wiring insulating layers, redistributions patterns and a cover insulating layer. The wiring structure includes wiring layers having a multilayer wiring structure and via plugs. The first inter-wiring insulating layer that surrounds the wiring structure on a substrate. The second inter-wiring insulating layer is on the first inter-wiring insulating layer, and redistribution via plugs are connected to the wiring structure through the second inter-wiring insulating layer. The redistribution patterns includes pad patterns and dummy patterns on the second inter-wiring insulating layer. Each patterns has a thickness greater than a thickness of each wiring layer. The cover insulating layer covers some of the redistribution patterns. The dummy patterns are in the form of lines that extend in a horizontal direction parallel to the substrate.

In some aspects, the techniques described herein relate to an electronic device including: a substrate; a metallization layer, the metallization layer having: a first surface disposed on the substrate; a second surface opposite the first surface; and a corrosion-prevention implant layer disposed in the metallization layer, the corrosion-prevention implant layer extending from the second surface to a depth from the second surface in the metallization layer, the depth being less than a thickness of the metallization layer; and an electrical connector coupled with the second surface.

An SiC semiconductor device includes an SiC semiconductor layer of a first conductivity type having a main surface, a source trench formed in the main surface and having a side wall and a bottom wall, a source electrode embedded in the source trench and having a side wall contact portion in contact with a region of the side wall of the source trench at an opening side of the source trench, a body region of a second conductivity type formed in a region of a surface layer portion of the main surface along the source trench, and a source region of the first conductivity type electrically connected to the side wall contact portion of the source electrode in a surface layer portion of the body region.

Disclosed are semiconductor devices and methods of fabricating the same. The semiconductor device includes a first dielectric layer including a first pad, a second dielectric layer on the first dielectric layer, a through electrode that penetrates the second dielectric layer and is electrically connected to the first pad, an upper passivation layer on the second dielectric layer, a second pad on the upper passivation layer, and an upper barrier layer between the upper passivation layer and the second pad. The first pad and the through electrode include a first material. The second pad includes a second material that is different from the first material of the first pad and the through electrode. The second pad includes a first part on the upper passivation layer, and a second part that extends from the first part into the upper passivation layer and is connected to the through electrode.

A semiconductor package may include: a base layer; first to Nth semiconductor chips (N is a natural number of 2 or more) sequentially offset stacked over the base layer so that a chip pad portion of one side edge region is exposed, wherein the chip pad portion includes a chip pad and includes a redistribution pad that partially contacts the chip pad and extends away from the chip pad; and a bonding wire connecting the chip pad of a kth semiconductor chip among the first to Nth semiconductor chips to the redistribution pad of a k1th semiconductor chip or a k+1th semiconductor chip when k is a natural number greater than 1 and the bonding wire connecting the chip pad of the kth semiconductor chip to a pad of the base layer or the redistribution pad of the k+1th semiconductor chip when k is 1.

The present disclosure provides a semiconductor device including: a semiconductor substrate; a conductive film covering a front face of the semiconductor substrate, a front face of the conductive film having plural straight-line shaped concave portions disposed in parallel to each other; and a protecting film covering the front face of the conductive film, the protecting film having an opening that has an edge forming an angle with the plural concave portions of greater than 0 and less than 90, and that partially exposes the conductive film.

A semiconductor device has a first semiconductor die with a base material. A covering layer is formed over a surface of the base material. The covering layer can be made of an insulating material or metal. A trench is formed in the surface of the base material. The covering layer extends into the trench to provide the cantilevered protrusion of the covering layer. A portion of the base material is removed by plasma etching to form a cantilevered protrusion extending beyond an edge of the base material. The cantilevered protrusion can be formed by removing the base material to the covering layer, or the cantilevered protrusion can be formed within the base material under the covering layer. A second semiconductor die is disposed partially under the cantilevered protrusion. An interconnect structure is formed between the cantilevered protrusion and second semiconductor die.

An electronic device includes a semiconductor body and a dielectric layer extending over the semiconductor body. A galvanic isolation module includes a first metal region extending in the dielectric layer at a first height and a second metal region extending in the dielectric layer at a second height greater than the first height. The first and second metal regions are capacitively or magnetically coupleable together. The second metal region includes a side wall and a bottom wall coupled to one another through rounded surface portions.