A microelectronic device, in a multirow gull-wing chip scale package, has a die connected to intermediate pads by wire bonds. The intermediate pads are free of photolithographically-defined structures. An encapsulation material at least partially surrounds the die and the wire bonds, and contacts the intermediate pads. Inner gull-wing leads and outer gull-wing leads, located outside of the encapsulation material, are attached to the intermediate pads. The gull-wing leads have external attachment surfaces opposite from the intermediate pads. The external attachment surfaces of the outer gull-wing leads are located outside of the external attachment surfaces of the inner gull-wing leads. The microelectronic device is formed by mounting the die on a carrier, forming the intermediate pads without using a photolithographic process, and forming the wire bonds. The encapsulation material is formed, and the carrier is subsequently removed, exposing the intermediate pads. The gull-wing leads are formed on the intermediate pads.

A microelectronic device, in a multirow gull-wing chip scale package, has a die connected to intermediate pads by wire bonds. The intermediate pads are free of photolithographically-defined structures. An encapsulation material at least partially surrounds the die and the wire bonds, and contacts the intermediate pads. Inner gull-wing leads and outer gull-wing leads, located outside of the encapsulation material, are attached to the intermediate pads. The gull-wing leads have external attachment surfaces opposite from the intermediate pads. The external attachment surfaces of the outer gull-wing leads are located outside of the external attachment surfaces of the inner gull-wing leads. The microelectronic device is formed by mounting the die on a carrier, forming the intermediate pads without using a photolithographic process, and forming the wire bonds. The encapsulation material is formed, and the carrier is subsequently removed, exposing the intermediate pads. The gull-wing leads are formed on the intermediate pads.

A semiconductor package is disclosed. The disclosed semiconductor package includes a substrate having bonding pads at an upper surface thereof, a lower semiconductor chip, at least one upper semiconductor chip disposed on the lower semiconductor chip, and a dam structure having a closed loop shape surrounding the lower semiconductor chip. The dam structure includes narrow and wide dams disposed between the lower semiconductor chip and the bonding pads. The wide dam has a greater inner width than the narrow dam. The semiconductor packages further includes an underfill disposed inside the dam structure and being filled between the substrate and the lower semiconductor chip.

A semiconductor package is disclosed. The disclosed semiconductor package includes a substrate having bonding pads at an upper surface thereof, a lower semiconductor chip, at least one upper semiconductor chip disposed on the lower semiconductor chip, and a dam structure having a closed loop shape surrounding the lower semiconductor chip. The dam structure includes narrow and wide dams disposed between the lower semiconductor chip and the bonding pads. The wide dam has a greater inner width than the narrow dam. The semiconductor packages further includes an underfill disposed inside the dam structure and being filled between the substrate and the lower semiconductor chip.

A package structure is provided. The package structure includes a die, a lead frame, and a conductive glue. The lead frame includes a die pad and a retaining wall structure. The die pad is configured to support the die, and the retaining wall structure surrounds the die. The conductive glue is disposed between the die and the lead frame.

A package structure is provided. The package structure includes a die, a lead frame, and a conductive glue. The lead frame includes a die pad and a retaining wall structure. The die pad is configured to support the die, and the retaining wall structure surrounds the die. The conductive glue is disposed between the die and the lead frame.

According to one embodiment, a semiconductor device includes a semiconductor chip having a first electrode on a first surface, a metal plate, and a first conductive bonding sheet that is disposed between the first surface of the semiconductor chip and the metal plate and bonds the first electrode to the metal plate.

According to one embodiment, a semiconductor device includes a semiconductor chip having a first electrode on a first surface, a metal plate, and a first conductive bonding sheet that is disposed between the first surface of the semiconductor chip and the metal plate and bonds the first electrode to the metal plate.

A semiconductor package assembly includes a carrier with a die attach surface and a contact pad separated from the die attach surface, a semiconductor die mounted on the die attach surface, the semiconductor die having a front side metallization that faces away from the die attach surface, an interconnect ribbon attached to the semiconductor die and the contact pad such that the interconnect ribbon electrically connects the front side metallization to the contact pad, and an electrically insulating encapsulant body that encapsulates the semiconductor die and at least part of the interconnect ribbon. The interconnect ribbon includes a layer stack of a first metal layer and a second layer formed on top of the first metal layer. The first metal layer includes a different metal as the second metal layer. The first metal layer faces the front side metallization.

A semiconductor package assembly includes a carrier with a die attach surface and a contact pad separated from the die attach surface, a semiconductor die mounted on the die attach surface, the semiconductor die having a front side metallization that faces away from the die attach surface, an interconnect ribbon attached to the semiconductor die and the contact pad such that the interconnect ribbon electrically connects the front side metallization to the contact pad, and an electrically insulating encapsulant body that encapsulates the semiconductor die and at least part of the interconnect ribbon. The interconnect ribbon includes a layer stack of a first metal layer and a second layer formed on top of the first metal layer. The first metal layer includes a different metal as the second metal layer. The first metal layer faces the front side metallization.