Abstract: Semiconductor packages having an electromagnetic interference (EMI) shielding layer and methods for forming the same are disclosed. The method includes providing a base carrier defined with an active region and a non-active region. A fan-out redistribution structure is formed over the base carrier. A die having elongated die contacts are provided. The die contacts corresponding to conductive pillars. The die contacts are in electrical communication with the fan-out redistribution structure. An encapsulant having a first major surface and a second major surface opposite to the first major surface is formed. The encapsulant surrounds the die contacts and sidewalls of the die. An electromagnetic interference (EMI) shielding layer is formed to line the first major surface and sides of the encapsulant. An etch process is performed after forming the EMI shielding layer to completely remove the base carrier and singulate the semiconductor package.

Abstract: Embodiments of the present invention are directed to a semiconductor package with improved thermal performance. The semiconductor package includes a package substrate comprising a top substrate surface and a bottom substrate surface. The package substrate comprises a thickness extending from the top substrate surface to the bottom substrate surface. A heat spreader is disposed on the top substrate surface. The heat spreader comprises a thickness extending from a top planar surface to a bottom planar surface of the heat spreader. The top planar surface of the heat spreader is defined with a die region and a non-die region surrounding the die region. A semiconductor die is directly disposed on the top planar surface of the heat spreader in the die region. The thickness of the heat spreader is greater relative to the thickness of the package substrate.

Abstract: Device and method of forming the device are disclosed. A device includes a buildup package substrate with top and bottom surfaces and a plurality of interlevel dielectric (ILD) layers with interconnect structures printed layer by layer and includes a die region and a non-die region on the top surface. A semiconductor die is disposed in the die and non-die regions of the package substrate and is electrically connected to the plurality of interconnect structures via a plurality of wire bonds. A plurality of conductive elements are disposed on the bottom surface of the package substrate and a dielectric layer encapsulates the semiconductor die, the wire bonds and the top surface of the buildup package substrate.

Abstract: Embodiments of the present invention are directed to a semiconductor package with improved thermal performance. The semiconductor package includes a package substrate comprising a top substrate surface and a bottom substrate surface. The package substrate comprises a thickness extending from the top substrate surface to the bottom substrate surface. A heat spreader is disposed on the top substrate surface. The heat spreader comprises a thickness extending from a top planar surface to a bottom planar surface of the heat spreader. The top planar surface of the heat spreader is defined with a die region and a non-die region surrounding the die region. A semiconductor die is directly disposed on the top planar surface of the heat spreader in the die region. The thickness of the heat spreader is greater relative to the thickness of the package substrate.

Abstract: Semiconductor packages having an electromagnetic interference (EMI) shielding layer and methods for forming the same are disclosed. The method includes providing a base carrier defined with an active region and a non-active region. A fan-out redistribution structure is formed over the base carrier. A die having elongated die contacts are provided. The die contacts corresponding to conductive pillars. The die contacts are in electrical communication with the fan-out redistribution structure. An encapsulant having a first major surface and a second major surface opposite to the first major surface is formed. The encapsulant surrounds the die contacts and sidewalls of the die. An electromagnetic interference (EMI) shielding layer is formed to line the first major surface and sides of the encapsulant. An etch process is performed after forming the EMI shielding layer to completely remove the base carrier and singulate the semiconductor package.

Abstract: Device and method of forming the device are disclosed. A device includes a buildup package substrate with top and bottom surfaces and a plurality of interlevel dielectric (ILD) layers with interconnect structures printed layer by layer and includes a die region and a non-die region on the top surface. A semiconductor die is disposed in the die and non-die regions of the package substrate and is electrically connected to the plurality of interconnect structures via a plurality of wire bonds. A plurality of conductive elements are disposed on the bottom surface of the package substrate and a dielectric layer encapsulates the semiconductor die, the wire bonds and the top surface of the buildup package substrate.

Abstract: A method of and device for making a semiconductor package. The method comprises etching a first side of a metallic piece forming a leadframe with one or more wire bonding pads, applying a first protective layer on the first side, etching a second side of the metallic piece forming one or more conductive terminals, and applying a second protective layer on the second side. The semiconductor package comprises wire bonding pads in pillars structure surrounding a die attached to the leadframe. One or more terminals are on the bottom side of the semiconductor package.

Abstract: Embodiments of the present invention are directed to leadframe area array packaging technology for fabricating an area array of I/O contacts. A manufactured package includes a polymer material substrate, an interconnect layer positioned on top of the polymer material substrate, a die coupled to the interconnect layer via wire bonds or conductive pillars, and a molding compound encapsulating the die, the interconnect layer and the wire bonds or conductive pillars. The polymer material is typically formed on a carrier before assembly and is not removed to act as the substrate of the manufactured package. The polymer material substrate has a plurality of through holes that exposes the interconnect layer at predetermined locations and enables solder ball mounting or solder printing directly to the interconnect layer. In some embodiments, the semiconductor package includes a relief channel in the polymer material substrate to improve the reliability performance of the manufactured package.

Abstract: A method of and device for making a semiconductor package. The method comprises etching a first side of a metallic piece forming a leadframe with one or more wire bonding pads, applying a first protective layer on the first side, etching a second side of the metallic piece forming one or more conductive terminals, and applying a second protective layer on the second side. The semiconductor package comprises wire bonding pads in pillars structure surrounding a die attached to the leadframe. One or more terminals are on the bottom side of the semiconductor package.

Abstract: Embodiments of the present invention are directed to leadframe area array packaging technology for fabricating an area array of I/O contacts. A manufactured package includes a polymer material substrate, an interconnect layer positioned on top of the polymer material substrate, a die coupled to the interconnect layer via wire bonds or conductive pillars, and a molding compound encapsulating the die, the interconnect layer and the wire bonds or conductive pillars. The polymer material is typically formed on a carrier before assembly and is not removed to act as the substrate of the manufactured package. The polymer material substrate has a plurality of through holes that exposes the interconnect layer at predetermined locations and enables solder ball mounting or solder printing directly to the interconnect layer. In some embodiments, the semiconductor package includes a relief channel in the polymer material substrate to improve the reliability performance of the manufactured package.

Abstract: Embodiments of the present invention are directed to leadframe area array packaging technology for fabricating an area array of I/O contacts. A manufactured package includes a polymer material substrate, an interconnect layer positioned on top of the polymer material substrate, a die coupled to the interconnect layer via wire bonds or conductive pillars, and a molding compound encapsulating the die, the interconnect layer and the wire bonds or conductive pillars. The polymer material is typically formed on a carrier before assembly and is not removed to act as the substrate of the manufactured package. The polymer material substrate has a plurality of through holes that exposes the interconnect layer at predetermined locations and enables solder ball mounting or solder printing directly to the interconnect layer. In some embodiments, the semiconductor package includes a relief channel in the polymer material substrate to improve the reliability performance of the manufactured package.

Abstract: Embodiments of the present invention are directed to leadframe area array packaging technology for fabricating an area array of I/O contacts. A manufactured package includes a polymer material substrate, an interconnect layer positioned on top of the polymer material substrate, a die coupled to the interconnect layer via wire bonds or conductive pillars, and a molding compound encapsulating the die, the interconnect layer and the wire bonds or conductive pillars. The polymer material is typically formed on a carrier before assembly and is not removed to act as the substrate of the manufactured package. The polymer material substrate has a plurality of through holes that exposes the interconnect layer at predetermined locations and enables solder ball mounting or solder printing directly to the interconnect layer. In some embodiments, the semiconductor package includes a relief channel in the polymer material substrate to improve the reliability performance of the manufactured package.