Abstract: A semiconductor wafer has integrated circuits formed thereon and a top passivation layer applied. The passivation layer is patterned and selectively etched to expose contact pads on each semiconductor die. The wafer is exposed to ionized gas causing the upper surface of passivation layer to roughen and to slightly roughen the upper surface of the contact pads. The wafer is cut to form a plurality of semiconductor dies each with a roughened passivation layer. The plurality of semiconductor dies are placed on an adhesive layer and a reconstituted wafer formed. Redistribution layers are formed to complete the semiconductor package having electrical contacts for establishing electrical connections external to the semiconductor package, after which the wafer is singulated to separate the dice.

Abstract: An eWLB package for 3D and PoP applications includes a redistribution layer on a support wafer. A semiconductor die is coupled to the redistribution layer, and solder balls are also positioned on the redistribution layer. The die and solder balls are encapsulated in a molding compound layer, which is planarized to expose top portions of the solder balls. A second redistribution layer is formed on the planarized surface of the molding compound layer. A ball grid array can be positioned on the second redistribution layer to couple the semiconductor package to a circuit board, or additional semiconductor dies can be added, each in a respective molding compound layer. The support wafer can act as an interposer, in which case it is processed to form TSVs in electrical contact with the first redistribution layer, and a redistribution layer is formed on the opposite side of the support substrate, as well.

Abstract: An embedded wafer level ball grid array (eWLB) is formed by embedding a semiconductor die in a molding compound. A trench is formed in the molding compound with a laser drill. A first layer of copper is deposited on the sidewall of the trench by physical vapor deposition. A second layer of copper is then formed on the first layer of copper by an electroless process. A third layer of copper is then formed on the second layer by electroplating.

Abstract: A system and method for reducing warpage of a semiconductor wafer. The system includes a device for securing the semiconductor wafer in a heating area. The device includes a holding mechanism for securing an edge of the semiconductor wafer. The device further includes a pressure reducing device that reduces the pressure underneath the semiconductor device, which further secures the semiconductor device in the heating area. The heating area includes a plurality of heating and cooling zones in which the semiconductor wafer is subjected to various temperatures.

Abstract: An embedded wafer level ball grid array (eWLB) is formed by embedding a semiconductor die in a molding compound. A trench is formed in the molding compound with a laser drill. A first layer of copper is deposited on the sidewall of the trench by physical vapor deposition. A second layer of copper is then formed on the first layer of copper by an electroless process. A third layer of copper is then formed on the second layer by electroplating.

Abstract: An integrated circuit package includes an integrated circuit die in a reconstituted substrate. The active side is processed then covered in molding compound while the inactive side is processed. The molding compound on the active side is then partially removed and solder balls are placed on the active side.

Abstract: An eWLB package for 3D and PoP applications includes a redistribution layer on a support wafer. A semiconductor die is coupled to the redistribution layer, and solder balls are also positioned on the redistribution layer. The die and solder balls are encapsulated in a molding compound layer, which is planarized to expose top portions of the solder balls. A second redistribution layer is formed on the planarized surface of the molding compound layer. A ball grid array can be positioned on the second redistribution layer to couple the semiconductor package to a circuit board, or additional semiconductor dies can be added, each in a respective molding compound layer. The support wafer can act as an interposer, in which case it is processed to form TSVs in electrical contact with the first redistribution layer, and a redistribution layer is formed on the opposite side of the support substrate, as well.

Abstract: A process for manufacturing a 3D or PoP semiconductor package includes forming a redistribution layer on a reconstituted wafer, then laser drilling a plurality of apertures in the reconstituted wafer, extending from an outer surface of the reconstituted wafer to intersect electrical traces in the first redistribution layer. A solder ball is then positioned adjacent to an opening of each of the apertures. The solder balls are melted and allowed to fill the apertures, making contact with the respective electrical traces and forming a plurality of solder columns. The outer surface of the reconstituted wafer is then planarized, and a second redistribution layer is formed on the planarized surface. The solder columns serve as through-vias, electrically coupling the first and second redistribution layers on opposite sides of the reconstituted wafer.

Abstract: A semiconductor packaging process includes drilling apertures in a reconstituted wafer, then filling the apertures with conductive paste by wiping a quantity of the paste across a back surface of the wafer so that paste is forced into the apertures. The paste is cured to form conductive posts. The wafer is thinned, and redistribution layers are formed on front and back surfaces of the wafer, with the posts acting as interconnections between the redistribution layers. In an alternative process, blind apertures are drilled. A dry film resist is applied to the front surface of the wafer, and patterned to expose the apertures. Conductive paste is applied from the front. To prevent paste from trapping air pockets in the apertures, the wiping process is performed under vacuum. After curing the paste, the wafer is thinned to expose the cured paste in the apertures, and redistribution layers are formed.

Abstract: A system and method for reducing warpage of a semiconductor wafer. The system includes a device for securing the semiconductor wafer in a heating area. The device includes a holding mechanism for securing an edge of the semiconductor wafer. The device further includes a pressure reducing device that reduces the pressure underneath the semiconductor device, which further secures the semiconductor device in the heating area. The heating area includes a plurality of heating and cooling zones in which the semiconductor wafer is subjected to various temperatures.

Abstract: A semiconductor wafer has integrated circuits formed thereon and a top passivation layer applied. The passivation layer is patterned and selectively etched to expose contact pads on each semiconductor die. The wafer is exposed to ionized gas causing the upper surface of passivation layer to roughen and to slightly roughen the upper surface of the contact pads. The wafer is cut to form a plurality of semiconductor dies each with a roughened passivation layer. The plurality of semiconductor dies are placed on an adhesive layer and a reconstituted wafer formed. Redistribution layers are formed to complete the semiconductor package having electrical contacts for establishing electrical connections external to the semiconductor package, after which the wafer is singulated to separate the dice.

Abstract: A semiconductor package and method of forming the same is described. The semiconductor package is formed from a semiconductor die cut from a semiconductor wafer that has a passivation layer. The semiconductor wafer is exposed to ionized gas causing the passivation layer to roughen. The semiconductor wafer is cut to form a plurality of semiconductor dies each with a roughened passivation layer. The plurality of semiconductor dies are placed on an adhesive layer to form a reconstituted wafer, and an encapsulation layer is formed enclosing the adhesive layer and the plurality of semiconductor dies. The passivation layer is removed and the semiconductor package formed includes electrical contacts for establishing electrical connections external to the semiconductor package.

Abstract: An embedded wafer level ball grid array (eWLB) is formed by embedding a semiconductor die in a molding compound. A trench is formed in the molding compound with a laser drill. A first layer of copper is deposited on the sidewall of the trench by physical vapor deposition. A second layer of copper is then formed on the first layer of copper by an electroless process. A third layer of copper is then formed on the second layer by electroplating.

Abstract: An embedded wafer level ball grid array (eWLB) is formed by embedding a semiconductor die in a molding compound. A trench is formed in the molding compound with a laser drill. A first layer of copper is deposited on the sidewall of the trench by physical vapor deposition. A second layer of copper is then formed on the first layer of copper by an electroless process. A third layer of copper is then formed on the second layer by electroplating.

Abstract: A flash memory storage device with PCI Express includes a microcontroller connected separately to a flash memory and a peripheral component interconnect (PCI) Express connecting interface, and the microcontroller has a flash memory interface and a PCI Express interface, such that when the storage device is coupled to a PCI Express disposed at a host through the PCI Express connecting interface, the host can save data into the storage device and the access rate can meet the standard of the transmission rate of the PCI Express so as to maximize the transmission rate of the storage device.