Abstract: A package includes a bottom substrate and a bottom die over and bonded to the bottom substrate. A metal-particle-containing compound material is overlying a top surface of the bottom die, wherein the metal-particle-containing compound material comprises metal particles. A molding material molds at least a lower part of the bottom die therein, wherein the molding material is overlying the bottom substrate.

Abstract: A luminous ball is provided, including a sphere, at least one covering spliced to wrap the sphere, at least one seam formed on an edge of the covering, a plurality of thread apertures disposed at two sides of the seam, at least one thread penetrating the plurality of thread apertures to stitch the edge of the covering between the two sides of the seam, and a light-emitting device disposed in the sphere. The light-emitting device includes a light-emitting unit, a power unit, and an electrical insulating unit breaking an electrical connection between the light-emitting unit and the power unit. The electrical insulating unit is removable. The electrical connection between the light-emitting unit and the power unit is provided when the electrical insulating unit is removed such that lights emitted by the light-emitting unit penetrate the sphere and are visible through the seam and the thread apertures.

Abstract: A method in which microelectronic devices are attached to a substrate surface, wherein spaces interpose neighboring ones of the microelectronic devices. Each microelectronic device has an outermost surface that is substantially parallel to the substrate surface. The substrate is closed in a transfer molding cavity of a transfer molding apparatus such that an internal surface of the transfer molding cavity contacts a substantial portion of each of the outermost surfaces of the microelectronic devices. A molding compound is subsequently injected into the transfer molding cavity, including into the spaces between ones of the plurality of microelectronic devices.

Abstract: A system and method for applying an underfill is provided. An embodiment comprises applying an underfill to a substrate and patterning the underfill. Once patterned other semiconductor devices, such as semiconductor dies or semiconductor packages may then be attached to the substrate through the underfill, with electrical connections from the other semiconductor devices extending into the pattern of the underfill.

Abstract: A packaging structure and a method of forming a packaging structure are provided. The packaging structure, such as an interposer, is formed by optionally bonding two carrier substrates together and simultaneously processing two carrier substrates. The processing includes forming a sacrificial layer over the carrier substrates. Openings are formed in the sacrificial layers and pillars are formed in the openings. Substrates are attached to the sacrificial layer. Redistribution lines may be formed on an opposing side of the substrates and vias may be formed to provide electrical contacts to the pillars. A debond process may be performed to separate the carrier substrates. Integrated circuit dies may be attached to one side of the redistribution lines and the sacrificial layer is removed.

Abstract: According to an exemplary embodiment, a substrate having a first area and a second area is provided. The substrate includes a plurality of pads. Each of the pads has a pad size. The pad size in the first area is larger than the pad size in the second area.

Abstract: A device comprises a first package component, and a first metal trace and a second metal trace on a top surface of the first package component. The device further includes a dielectric mask layer covering the top surface of the first package component, the first metal trace and the second metal trace, wherein the dielectric mask layer has an opening therein exposing the first metal trace. The device also includes a second package component and an interconnect formed on the second package component, the interconnect having a metal bump and a solder bump formed on the metal bump, wherein the solder bump contacts the first metal trace in the opening of the dielectric mask layer.

Abstract: A method of packaging includes placing a package component over a release film, wherein solder regions on a surface of the package component are in physical contact with the release film. Next, A molding compound filled between the release film and the package component is cured, wherein during the step of curing, the solder regions remain in physical contact with the release film.

Abstract: According to an exemplary embodiment, a semiconductor package is provided. The semiconductor package includes at least one chip, and at least one component adjacent to the at least one chip, wherein the at least one chip and the at least one component are molded in a same molding body.

Abstract: A system and method for applying an underfill is provided. An embodiment comprises applying an underfill to a substrate and patterning the underfill. Once patterned other semiconductor devices, such as semiconductor dies or semiconductor packages may then be attached to the substrate through the underfill, with electrical connections from the other semiconductor devices extending into the pattern of the underfill.

Abstract: Package structures and methods for forming the same are provided. A package structure includes a package layer. The package structure also includes an integrated circuit die and a first connector embedded in the package layer. The package structure further includes a redistribution layer over the package layer. The integrated circuit die is electrically connected to the redistribution layer through the first connector. In addition, the package structure includes a passivation layer over the redistribution layer. The package structure also includes a second connector over the passivation layer. A first portion of the redistribution layer and a second portion of the second connector extend into the passivation layer. The second portion of the second connector has a tapered profile along a direction from the integrated circuit die towards the first connector.

Abstract: A packaging structure and a method of forming a packaging structure are provided. The packaging structure, such as an interposer, is formed by optionally bonding two carrier substrates together and simultaneously processing two carrier substrates. The processing includes forming a sacrificial layer over the carrier substrates. Openings are formed in the sacrificial layers and pillars are formed in the openings. Substrates are attached to the sacrificial layer. Redistribution lines may be formed on an opposing side of the substrates and vias may be formed to provide electrical contacts to the pillars. A debond process may be performed to separate the carrier substrates. Integrated circuit dies may be attached to one side of the redistribution lines and the sacrificial layer is removed.

Abstract: A package includes a bottom substrate and a bottom die over and bonded to the bottom substrate. A metal-particle-containing compound material is overlying a top surface of the bottom die, wherein the metal-particle-containing compound material comprises metal particles. A molding material molds at least a lower part of the bottom die therein, wherein the molding material is overlying the bottom substrate.

Abstract: A package includes a package component, which further includes a top surface and a metal pad at the top surface of the package component. The package further includes a non-reflowable electrical connector over and bonded to the metal pad, and a molding material over the package component. The non-reflowable electrical connector is molded in the molding material and in contact with the molding material. The non-reflowable electrical connector has a top surface lower than a top surface of the molding compound.

Abstract: Packaged semiconductor devices and methods of packaging semiconductor devices are disclosed. In some embodiments, a packaged semiconductor device includes an integrated circuit die, a molding compound disposed around the integrated circuit die, and an interconnect structure disposed over the integrated circuit die and the molding compound. The molding compound is thicker than the integrated circuit die.

Abstract: Apparatus, and methods of manufacture thereof, in which a molding compound is formed between spaced apart microelectronic devices. The molding compound comprises micro-filler elements. No boundary of any of the micro-filler elements is substantially parallel to a substantially planar surface of the molding compound, or to a substantially planar surface of any of the microelectronic devices.

Abstract: Package structures and methods for forming the same are provided. A method for forming a package structure includes providing a carrier substrate. The method also includes forming a conductive layer over the carrier substrate. The method further includes forming a passivation layer over the conductive layer. The passivation layer includes openings that expose portions of the conductive layer. In addition, the method includes bonding integrated circuit dies to the portions of the conductive layer through bumps. There is a space between the integrated circuit dies and the passivation layer. The method also includes filling the space with a first molding compound. The first molding compound surrounds the bumps and the integrated circuit dies. The method further includes forming a second molding compound capping the first molding compound and the integrated circuit dies. The passivation layer has a sidewall that is covered by the second molding compound.

Abstract: Presented herein is a device processing boat comprising a base and at least one unit retainer disposed in the base. The device further comprises a cover having at least one recess configured to accept and retain at least one unit. The at least one recess is aligned over, and configured to hold the at least one unit over, at least a portion of the at least one unit retainer. The cover is retained to the device processing boat by the at least one unit retainer. At least one pressure sensor having at least one sensel is disposed in the base. The sensel is configured to sense a clamping force applied by the cover to the at least one unit.

Abstract: A method in which microelectronic devices are attached to a substrate surface, wherein spaces interpose neighboring ones of the microelectronic devices. Each microelectronic device has an outermost surface that is substantially parallel to the substrate surface. The substrate is closed in a transfer molding cavity of a transfer molding apparatus such that an internal surface of the transfer molding cavity contacts a substantial portion of each of the outermost surfaces of the microelectronic devices. A molding compound is subsequently injected into the transfer molding cavity, including into the spaces between ones of the plurality of microelectronic devices.

Abstract: A method of manufacturing a semiconductor package structure is provided. A stacked structure formed over the carrier substrate is provided, wherein the stacked structure has a channel with an opening. The stacked structure is immersed into a fluidic molding material to render the fluidic molding material flow into the channel through the openings.