Provided is a semiconductor device including a substrate, a pad, a protective layer, a plurality of convex patterns, a redistribution layer (RDL), and a bump. The pad is disposed on the substrate. The protective layer is disposed on the substrate. The protective layer has a first opening exposing a portion of a surface of the pad. The convex patterns are disposed on the protective layer. The RDL is disposed on the convex patterns. The RDL extends from the pad to the convex patterns. The bump is disposed on the convex patterns.

Provided is a semiconductor device including a substrate, a pad, a protective layer, a plurality of convex patterns, a redistribution layer (RDL), and a bump. The pad is disposed on the substrate. The protective layer is disposed on the substrate. The protective layer has a first opening exposing a portion of a surface of the pad. The convex patterns are disposed on the protective layer. The RDL is disposed on the convex patterns. The RDL extends from the pad to the convex patterns. The bump is disposed on the convex patterns.

The present disclosure relates to a technology relating to a power semiconductor module of which heat is dissipated through both sides thereof and provides a technology for maintaining a distance between an upper substrate and a lower substrate by a metal bump formed on one side of a power semiconductor die.

A semiconductor device has a semiconductor wafer and a first conductive layer formed over the semiconductor wafer as contact pads. A first insulating layer formed over the first conductive layer. A second conductive layer including an interconnect site is formed over the first conductive layer and first insulating layer. The second conductive layer is formed as a redistribution layer. A second insulating layer is formed over the second conductive layer. An opening is formed in the second insulating layer over the interconnect site. The opening extends to the first insulating layer in an area adjacent to the interconnect site. Alternatively, the opening extends partially through the second insulating layer in an area adjacent to the interconnect site. An interconnect structure is formed within the opening over the interconnect site and over a side surface of the second conductive layer. The semiconductor wafer is singulated into individual semiconductor die.

A method for interconnecting two conductors includes creating a first nickel layer on a first conductor of an electrical component, producing a first non-gold protective layer on the first nickel layer, the first non-gold protective layer being configured to prevent the first nickel layer from oxidizing, creating a second nickel layer on a second conductor, producing a second non-gold protective layer on the second nickel layer, the second non-gold protective layer being configured to prevent the second nickel layer from oxidizing, and interconnecting the first and second nickel layers using a solder layer that interfaces with the first and second nickel layers between the first and second conductors.

A semiconductor device includes a substrate with an opening formed through the substrate. A first electronic component is disposed over the substrate outside a footprint of the first opening. A second electronic component is disposed over the substrate opposite the first electrical component. A third electronic component is disposed over the substrate adjacent to the first electronic component. The substrate is disposed in a mold including a second opening of the mold over a first side of the substrate. The mold contacts the substrate between the first electronic component and the third electronic component. An encapsulant is deposited into the second opening. The encapsulant flows through the first opening to cover a second side of the substrate. In some embodiments, a mold film is disposed in the mold, and an interconnect structure on the substrate is embedded in the mold film.

A representative system and method for manufacturing stacked semiconductor devices includes disposing an aqueous alkaline solution between a first semiconductor device and a second semiconductor device prior to bonding. In a representative implementation, first and second semiconductor devices may be hybrid bonded to one another, where dielectric features of the first semiconductor device are bonded to dielectric features of the second semiconductor device, and metal features of the first semiconductor device are bonded to metal features of the second semiconductor device. Immersion bonds so formed demonstrate a substantially lower incidence of delamination associated with bond defects.

An integrated circuit component includes a semiconductor substrate, conductive pads, a passivation layer and conductive vias. The semiconductor substrate has an active surface. The conductive pads are located on the active surface of the semiconductor substrate and electrically connected to the semiconductor substrate, and the conductive pads each have a contact region and a testing region, where in each of the conductive pads, an edge of the contact region is in contact with an edge of the testing region. The passivation layer is located on the semiconductor substrate, where the conductive pads are located between the semiconductor substrate and the passivation layer, and the testing regions and the contact regions of the conductive pads are exposed by the passivation layer. The conductive vias are respectively located on the contact regions of the conductive pads.

An integrated circuit component includes a semiconductor substrate, conductive pads, a passivation layer and conductive vias. The semiconductor substrate has an active surface. The conductive pads are located on the active surface of the semiconductor substrate and electrically connected to the semiconductor substrate, and the conductive pads each have a contact region and a testing region, where in each of the conductive pads, an edge of the contact region is in contact with an edge of the testing region. The passivation layer is located on the semiconductor substrate, where the conductive pads are located between the semiconductor substrate and the passivation layer, and the testing regions and the contact regions of the conductive pads are exposed by the passivation layer. The conductive vias are respectively located on the contact regions of the conductive pads.

Methods, techniques, and structures relating to die packaging. In one exemplary implementation, a die package interconnect structure includes a semiconductor substrate and a first conducting layer in contact with the semiconductor substrate. The first conducting layer may include a base layer metal. The base layer metal may include Cu. The exemplary implementation may also include a diffusion barrier in contact with the first conducting layer and a wetting layer on top of the diffusion barrier. A bump layer may reside on top of the wetting layer, in which the bump layer may include Sn, and Sn may be electroplated. The diffusion barrier may be electroless and may be adapted to prevent Cu and Sn from diffusing through the diffusion barrier. Furthermore, the diffusion barrier may be further adapted to suppress a whisker-type formation in the bump layer.