A semiconductor device has a substrate. A plurality of conductive vias is formed through the substrate. A conductive layer is formed over the substrate. An insulating layer is formed over conductive layer. A portion of the substrate is removed to expose the conductive vias. A plurality of vertical interconnect structures is formed over the substrate. A first semiconductor die is disposed over the substrate. A height of the vertical interconnect structures is less than a height of the first semiconductor die. An encapsulant is deposited over the first semiconductor die and the vertical interconnect structures. A first portion of the encapsulant is removed from over the first semiconductor die while leaving a second portion of the encapsulant over the vertical interconnect structures. The second portion of the encapsulant is removed to expose the vertical interconnect structures. A second semiconductor die is disposed over the first semiconductor die.

An underfill film material and a method for manufacturing a semiconductor device using the same which enables voidless mounting and favorable solder bonding properties are provided. An underfill material is used which contains an epoxy resin, an acid anhydride, an acrylic resin and an organic peroxide, the underfill material exhibits non-Bingham fluidity at a temperature ranging from 60° C. to 100° C., a storage modulus G′ measured by dynamic viscosity measurement has an inflection point in an angular frequency region below 10E+02 rad/s, and the storage modulus G′ in the angular frequency below the inflection point is 10E+05 Pa or more and 10E+06 Pa or less. This enables voidless packaging and excellent solder connection properties.

An underfill film material and a method for manufacturing a semiconductor device using the same which enables voidless mounting and favorable solder bonding properties are provided. An underfill material is used which contains an epoxy resin, an acid anhydride, an acrylic resin and an organic peroxide, the underfill material exhibits non-Bingham fluidity at a temperature ranging from 60° C. to 100° C., a storage modulus G′ measured by dynamic viscosity measurement has an inflection point in an angular frequency region below 10E+02 rad/s, and the storage modulus G′ in the angular frequency below the inflection point is 10E+05 Pa or more and 10E+06 Pa or less. This enables voidless packaging and excellent solder connection properties.

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 package includes a semiconductor die having an active surface and a bottom surface opposite to the active surface; a plurality of bond pads distributed on the active surface of the semiconductor die; an encapsulant covering the active surface of the semiconductor die, wherein the encapsulant comprises a bottom surface that is flush with the bottom surface of the semiconductor; and a plurality of printed interconnect features embedded in the encapsulant for electrically connecting the plurality of bond pads. Each of the printed interconnect features comprises a conductive wire and a conductive pad being integral with the conductive wire.

A semiconductor package includes a semiconductor die having an active surface and a bottom surface opposite to the active surface; a plurality of bond pads distributed on the active surface of the semiconductor die; an encapsulant covering the active surface of the semiconductor die, wherein the encapsulant comprises a bottom surface that is flush with the bottom surface of the semiconductor; and a plurality of printed interconnect features embedded in the encapsulant for electrically connecting the plurality of bond pads. Each of the printed interconnect features comprises a conductive wire and a conductive pad being integral with the conductive wire.

An integrated circuit (IC) package is described. The IC package includes a first die having a first power delivery network on the first die. The IC package also includes a second die having a second power delivery network on the second die. The first die is stacked on the second die. The IC package further includes package voltage regulators integrated with and coupled to the first die and/or the second die within a package core of the integrated circuit package.

An integrated circuit (IC) package is described. The IC package includes a first die having a first power delivery network on the first die. The IC package also includes a second die having a second power delivery network on the second die. The first die is stacked on the second die. The IC package further includes package voltage regulators integrated with and coupled to the first die and/or the second die within a package core of the integrated circuit package.

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.