Abstract: BGA packages with a spatially varied ball height, molds and techniques to form such packages. A template or mold with cavities may be pre-fabricated to hold solder paste material applied to the mold, for example with a solder paste printing process. The depth and/or diameter of the cavities may be predetermined as a function of spatial position within the mold working surface area. Mold cavity dimensions may be specified corresponding to package position to account for one or more pre-existing or expected spatial variations in the package, such as a package-level warpage measurement. Any number of different ball heights may be provided. The molds may be employed in a standardize process that need not be modified with each change in the mold.

Abstract: A helically wound insulated twinax cable reduces cable dielectric loss by increasing the percentage of air in the dielectric filler surrounding the signal conductors. The helical insulator wire winding further provides mechanical support and reduces the risk of creating an electrical short-circuit. This will improve differential signaling capability of the two-conductor cable and enable longer cable range.

Abstract: BGA packages with a spatially varied ball height, molds and techniques to form such packages. A template or mold with cavities may be pre-fabricated to hold solder paste material applied to the mold, for example with a solder paste printing process. The depth and/or diameter of the cavities may be predetermined as a function of spatial position within the mold working surface area. Mold cavity dimensions may be specified corresponding to package position to account for one or more pre-existing or expected spatial variations in the package, such as a package-level warpage measurement. Any number of different ball heights may be provided. The molds may be employed in a standardize process that need not be modified with each change in the mold.

Abstract: Described is an apparatus which comprises: a squeegee head which is operable to drop a material; and a vacuum manifold attachable to the squeegee head, wherein the vacuum manifold is operable to create a vacuum in a space prior to the squeegee head is to drop the material.

Abstract: Discussed generally herein are methods and devices including or providing an electromagnetic interference (EMI) shielding. A device can include a substrate including electrical connection circuitry therein, grounding circuitry on, or at least partially in the substrate, the grounding circuitry at least partially exposed from a surface of the substrate, a die electrically connected to the connection circuitry and the grounding circuitry, the die on the substrate, and a conductive foil or conductive film surrounding the die, the conductive foil or conductive film electrically connected to the grounding circuitry.

Abstract: Methods of fabricating a microelectronic device comprising forming a microelectronic substrate having a plurality microelectronic device attachment bond pads and at least one interconnection bond pad formed in and/or on an active surface thereof, attaching a microelectronic device to the plurality of microelectronic device attachment bond pads, forming a mold chase having a mold body and at least one projection extending from the mold body, wherein the at least one projection includes at least one sidewall and a contact surface, contacting the mold chase projection contact surface to a respective microelectronic substrate interconnection bond pad, disposing a mold material between the microelectronic substrate and the mold chase, and removing the mold chase to form at least one interconnection via extending from a top surface of the mold material to a respective microelectronic substrate interconnection bond pad.

Abstract: Embodiments describe a semiconductor package that includes a substrate, a die bonded to the substrate, and a solder paste overmold layer formed over a top surface of the die. In an embodiment, the solder paste comprises a high-melting point metal, a solder matrix, intermetallic compounds and a polymer. The overmold layer has a high elastic modulus, a coefficient of thermal expansion similar to the substrate, and reduces the warpage of the package. In an embodiment, interconnects of a semiconductor package are formed with a no-slump solder paste that includes vents. Vents may be formed through a conductive network formed by the high-melting point metal, solder matrix and intermetallic compounds. In an embodiment, vents provide a path through the interconnect that allows for moisture outgassing. In an embodiment, a mold layer may be mechanically anchored to the interconnects by the vents, thereby providing improved mechanical continuity to the mold layer.

Abstract: Embodiments are generally directed to electromagnetic interference shielding for system-in-package technology. An embodiment of a system-in-package includes a substrate; chips and components attached to the substrate; dielectric molding over the chips and components; and an electromagnetic interference (EMI) shield. The EMI shield formed from a conductive paste, and the EMI shield provides a combined internal EMI shield between chips and components of the system in package and external EMI shield for the system-in-package.

Abstract: Semiconductor packages with electromagnetic interference (EMI) shielding and a method of manufacture therefor is disclosed. The semiconductor packages may house single electronic component or may be a system in a package (SiP) implementation. The EMI shielding may be provided on top of and along the periphery of the semiconductor package. The EMI shielding on the periphery may be formed of cured conductive ink or cured conductive paste disposed on sidewalls of molding that encapsulates the electronic component(s) provided on the semiconductor package. The vertical portions of the EMI shielding, including EMI shielding on the periphery may be formed by filling conductive ink in trenches formed in-situ with curing the molding. The top portion of the EMI shielding and the may additionally be cured conductive ink.

Abstract: Die warpage is controlled for the assembly of thin dies. In one example, a semiconductor die has a back side and a front side opposite the back side. The back side has a semiconductor substrate and the front side has components formed over the semiconductor substrate in front side layers. A backside layer is formed over the backside of the semiconductor die to resist warpage of the die when the die is heated and a plurality of contacts are formed on the front side of the die to attach to a substrate.

Abstract: Embodiments describe a semiconductor package that includes a substrate, a die bonded to the substrate, and a solder paste overmold layer formed over a top surface of the die. In an embodiment, the solder paste comprises a high-melting point metal, a solder matrix, intermetallic compounds and a polymer. The overmold layer has a high elastic modulus, a coefficient of thermal expansion similar to the substrate, and reduces the warpage of the package. In an embodiment, interconnects of a semiconductor package are formed with a no-slump solder paste that includes vents. Vents may be formed through a conductive network formed by the high-melting point metal, solder matrix and intermetallic compounds. In an embodiment, vents provide a path through the interconnect that allows for moisture outgassing. In an embodiment, a mold layer may be mechanically anchored to the interconnects by the vents, thereby providing improved mechanical continuity to the mold layer.

Abstract: Vacuum processing, such as a backside metallization (BSM) deposition, is performed on a taped wafer after a gas escape path is formed between a base film of the tape and the wafer frontside surface following backgrind. Venting provided by the gas escape path reduces formation of bubbles under the tape. The gas escape path may be provided, for example, by a selective pre-curing of tape adhesive, to breach an edge seal and place the wafer frontside surface internal to the edge seal in fluid communication with an environment external to the edge seal. With the thinned wafer supported by the pre-cured tape, BSM is then deposited while the wafer and tape are cooled, for example, via a cooled electrostatic chuck.

Abstract: Methods of fabricating a microelectronic device comprising forming a microelectronic substrate having a plurality microelectronic device attachment bond pads and at least one interconnection bond pad formed in and/or on an active surface thereof, attaching a microelectronic device to the plurality of microelectronic device attachment bond pads, forming a mold chase having a mold body and at least one projection extending from the mold body, wherein the at least one projection includes at least one sidewall and a contact surface, contacting the mold chase projection contact surface to a respective microelectronic substrate interconnection bond pad, disposing a mold material between the microelectronic substrate and the mold chase, and removing the mold chase to form at least one interconnection via extending from a top surface of the mold material to a respective microelectronic substrate interconnection bond pad.

Abstract: Vacuum processing, such as a backside metallization (BSM) deposition, is performed on a taped wafer after a gas escape path is formed between a base film of the tape and the wafer frontside surface following backgrind. Venting provided by the gas escape path reduces formation of bubbles under the tape. The gas escape path may be provided, for example, by a selective pre-curing of tape adhesive, to breach an edge seal and place the wafer frontside surface internal to the edge seal in fluid communication with an environment external to the edge seal. With the thinned wafer supported by the pre-cured tape, BSM is then deposited while the wafer and tape are cooled, for example, via a cooled electrostatic chuck.

Abstract: Die warpage is controlled for the assembly of thin dies. In one example, a semiconductor die has a back side and a front side opposite the back side. The back side has a semiconductor substrate and the front side has components formed over the semiconductor substrate in front side layers. A backside layer is formed over the backside of the semiconductor die to resist warpage of the die when the die is heated and a plurality of contacts are formed on the front side of the die to attach to a substrate.

Abstract: Embodiments describe a semiconductor package that includes a substrate, a die bonded to the substrate, and a solder paste overmold layer formed over a top surface of the die. In an embodiment, the solder paste comprises a high-melting point metal, a solder matrix, intermetallic compounds and a polymer. The overmold layer has a high elastic modulus, a coefficient of thermal expansion similar to the substrate, and reduces the warpage of the package. In an embodiment, interconnects of a semiconductor package are formed with a no-slump solder paste that includes vents. Vents may be formed through a conductive network formed by the high-melting point metal, solder matrix and intermetallic compounds. In an embodiment, vents provide a path through the interconnect that allows for moisture outgassing. In an embodiment, a mold layer may be mechanically anchored to the interconnects by the vents, thereby providing improved mechanical continuity to the mold layer.

Abstract: Die warpage is controlled for the assembly of thin dies. In one example, a device having a substrate on a back side and components in front side layers is formed. A backside layer is formed over the substrate, the layer resisting warpage of the device when the device is heated. The device is attached to a substrate by heating.

Abstract: Die warpage is controlled for the assembly of thin dies. In one example, a device having a substrate on a back side and components in front side layers is formed. A backside layer is formed over the substrate, the layer resisting warpage of the device when the device is heated. The device is attached to a substrate by heating.

Abstract: Vacuum processing, such as a backside metallization (BSM) deposition, is performed on a taped wafer after a gas escape path is formed between a base film of the tape and the wafer frontside surface following backgrind. Venting provided by the gas escape path reduces formation of bubbles under the tape. The gas escape path may be provided, for example, by a selective pre-curing of tape adhesive, to breach an edge seal and place the wafer frontside surface internal to the edge seal in fluid communication with an environment external to the edge seal. With the thinned wafer supported by the pre-cured tape, BSM is then deposited while the wafer and tape are cooled, for example, via a cooled electrostatic chuck.

Abstract: Formulations and processes for forming wafer coat layers are disclosed. In one embodiment, an organic surface protectant is incorporated into a wafer coat formulation deposited onto a semiconductor wafer prior to the laser scribe operation. Upon removal of the wafer coat layer, the organic surface protectant remains on the bumps and thereby prevents oxidation of the bumps between die prep and chip and attach. In an alternative embodiment, an ultraviolet light absorber is added to the wafer coat formulation to enhance the wafer coat layer's energy absorption and thereby improve the laser's ability to ablate the wafer coat layer. In an alternative embodiment, a conformal wafer coat layer is deposited on the wafer and die bumps, thereby reducing wafer coat layer thickness variations that can impact the laser scribing ability.