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.

Interconnect structures and methods of forming the same are provided. An interconnect structure according to the present disclosure includes a conductive line feature over a substrate, a conductive etch stop layer over the conductive line feature, a contact via over the conductive etch stop layer, and a barrier layer disposed along a sidewall of the conductive line feature, a sidewall of the conductive etch stop layer, and a sidewall of the contact via.

A semiconductor module includes: a first power semiconductor element that includes a first main current electrode; a main body that accommodates therein the first power semiconductor element; and a first main current terminal connectable to the first main current electrode. The main body includes: a top face; a side face that connects to the top face; a bottom face fixable to a cooler; and a recessed portion that is on the side face, and accommodates therein an end portion of an insulating member. The first main current terminal protrudes from the side face of the main body, and includes: a first face; and a second face on an opposite side of the first face. The second face is closer to the bottom face than the first face on the side face. The recessed portion is on the side face between the bottom face and the second face, and is at a position apart from the bottom face.

A semiconductor chip stack module that includes a substrate, two first semiconductor chips supported by the substrate, and a second semiconductor chip stacked on both of the two first semiconductor chips. The second semiconductor chip is electrically connected to both of the two first semiconductor chips by a conductive paste configured between the second semiconductor chip and both of the two first semiconductor chips. As multiple standard chips are stacked in the power module, and their number as well as the connection methods (e.g. series or parallel) are flexible so that the user can choose which electric characteristic(s) to be increased in the power module with the stacked chips.

A performance of a semiconductor device is improved. The semiconductor device includes a semiconductor chip, and a clip mounted on the semiconductor chip via a silver paste. Here, the semiconductor chip includes a passivation film having an opening, a source pad of a main transistor having a portion exposed from the passivation film at the opening, and a wall portion provided on the passivation film so as to surround the source pad in a plan view. At this time, a whole of the portion (exposed surface) of the source pad, which is exposed from the passivation film, is covered with the silver paste. Further, in the plan view, the silver paste connecting the source pad with the clip is positioned inside of an area surrounded by the wall portion, without overflowing.

A semiconductor device includes: a semiconductor element that includes an element main body having an element main surface facing one side in a thickness direction, and a first electrode arranged on the element main surface; a first insulating layer that is arranged over a peripheral edge portion of the first electrode and the element main surface and includes a first annular portion formed in an annular shape when viewed in the thickness direction; and a second insulating layer that is laminated on the first insulating layer, is made of a resin material, and includes a second annular portion overlapping with the first annular portion when viewed in the thickness direction.

A semiconductor die and an electrically conductive ribbon are arranged on a substrate. The electrically conductive ribbon includes a roughened surface. An insulating encapsulation is molded onto the semiconductor die and the electrically conductive ribbon. The roughened surface of the electrically conductive ribbon provides a roughened coupling interface to the insulating encapsulation.

First conductive layer is connected to an impurity region which is a source region or an emitter region. A first conductive layer having an emitter pad and a second conductive layer having a Kelvin emitter pad and a relay pad are separated. A plane occupied area of the Kelvin emitter pad is smaller than a plane occupied area of the emitter pad.

A variety of footed and leadless semiconductor packages, with either exposed or isolated die pads, are described. Some of the packages have leads with highly coplanar feet that protrude from a plastic body, facilitating mounting the packages on printed circuit boards using wave-soldering techniques.

A power semiconductor device including a first and second die, each including a plurality of conductive contact regions and a passivation region including a number of projecting dielectric regions and a number of windows. Adjacent windows are separated by a corresponding projecting dielectric region with each conductive contact region arranged within a corresponding window. A package of the surface mount type houses the first and second dice. The package includes a first bottom insulation multilayer and a second bottom insulation multilayer carrying, respectively, the first and second dice. A covering metal layer is arranged on top of the first and second dice and includes projecting metal regions extending into the windows to couple electrically with corresponding conductive contact regions. The covering metal layer moreover forms a number of cavities, which are interposed between the projecting metal regions so as to overlie corresponding projecting dielectric regions.