A pad is disposed on a substrate. A bump structure is disposed on the pad and electrically connected to the pad. The bump structure includes a first copper layer and a second copper layer sequentially stacked on the pad and a solder ball on the second copper layer. A first X-ray diffraction (XRD) peak intensity ratio of (111) plane to (200) plane of the first copper layer is greater than a second XRD peak intensity ratio of (111) plane to (200) plane of the second copper layer.

A flip chip device and methods for fabrication are provided. An interconnect layer for a device include a plurality of solder bumps arranged within the interconnect layer. A first subset of the plurality of solder bumps has a first cross-sectional area, where the first subset is arranged along a first position at a first edge of the interconnect layer. A second subset of the plurality of solder bumps has a second cross-sectional area, where the second subset is arranged at a second position of the interconnect layer. A third subset of the plurality of solder bumps is arranged between the first position and the second position, where the third subset has a plurality of cross-sectional areas.

Integrated circuit packages and methods of forming the same are provided. One or more redistribution layers are formed on a carrier. First connectors are formed on a first side of the RDLs. Dies are bonded to the first side of the RDLs using the first connectors. An encapsulant is formed on the first side of the RDLs around the dies. The carrier is de-bonded from the overlaying structure and second connectors are formed on a second side of the RDLs. The resulting structure in diced to form individual packages.

Integrated circuit packages and methods of forming the same are provided. One or more redistribution layers are formed on a carrier. First connectors are formed on a first side of the RDLs. Dies are bonded to the first side of the RDLs using the first connectors. An encapsulant is formed on the first side of the RDLs around the dies. The carrier is de-bonded from the overlaying structure and second connectors are formed on a second side of the RDLs. The resulting structure in diced to form individual packages.

A semiconductor device has a plurality of conductive vias formed into a semiconductor wafer. A portion of the semiconductor wafer is removed so the conductive vias extend above a surface of the semiconductor wafer. A notch is formed in the semiconductor wafer around each of the conductive vias. The notch around the conductive vias can be formed by wet etching, dry etching, or LDA. A first insulating layer is formed over a surface of the semiconductor wafer and conductive vias and into the notch to provide stress relief between the conductive vias and semiconductor wafer. A portion of the first insulating layer is removed to expose the conductive vias. A first conductive layer and second insulating layer can be formed around the conductive vias. A second conductive layer can be formed over the conductive vias. The notch can extend into the second insulating layer.

A semiconductor device has a plurality of conductive vias formed into a semiconductor wafer. A portion of the semiconductor wafer is removed so the conductive vias extend above a surface of the semiconductor wafer. A notch is formed in the semiconductor wafer around each of the conductive vias. The notch around the conductive vias can be formed by wet etching, dry etching, or LDA. A first insulating layer is formed over a surface of the semiconductor wafer and conductive vias and into the notch to provide stress relief between the conductive vias and semiconductor wafer. A portion of the first insulating layer is removed to expose the conductive vias. A first conductive layer and second insulating layer can be formed around the conductive vias. A second conductive layer can be formed over the conductive vias. The notch can extend into the second insulating layer.

In a semiconductor device (SP1) according to an embodiment, a solder resist film (first insulating layer, SR1) which is in contact with the base material layer, and a resin body (second insulating layer, 4) which is in contact with the solder resist film and the semiconductor chip, are laminated in between the base material layer (2CR) of a wiring substrate 2 and a semiconductor chip (3). In addition, a linear expansion coefficient of the solder resist film is equal to or larger than a linear expansion coefficient of the base material layer, and the linear expansion coefficient of the solder resist film is equal to or smaller than a linear expansion coefficient of the resin body. Also, the linear expansion coefficient of the base material layer is smaller than the linear expansion coefficient of the resin body. According to the above-described configuration, damage of the semiconductor device caused by a temperature cyclic load can be suppressed, and thereby reliability can be improved.

In a semiconductor device (SP1) according to an embodiment, a solder resist film (first insulating layer, SR1) which is in contact with the base material layer, and a resin body (second insulating layer, 4) which is in contact with the solder resist film and the semiconductor chip, are laminated in between the base material layer (2CR) of a wiring substrate 2 and a semiconductor chip (3). In addition, a linear expansion coefficient of the solder resist film is equal to or larger than a linear expansion coefficient of the base material layer, and the linear expansion coefficient of the solder resist film is equal to or smaller than a linear expansion coefficient of the resin body. Also, the linear expansion coefficient of the base material layer is smaller than the linear expansion coefficient of the resin body. According to the above-described configuration, damage of the semiconductor device caused by a temperature cyclic load can be suppressed, and thereby reliability can be improved.

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 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.