Abstract: Structures and formation methods of a chip package are provided. The method includes forming multiple conductive structures over a carrier substrate and disposing a semiconductor die over the carrier substrate. The method also includes disposing a mold over the carrier substrate. The method further includes forming a protection layer between the mold and the carrier substrate to surround the semiconductor die and the conductive structures. In addition, the method includes removing the mold.

Abstract: Various embodiments of mechanisms for forming a die package using a compressive dielectric layer to contact and to surround through substrate vias (TSVs) in the die package are provided. The compressive dielectric layer reduces or eliminates bowing of the die package. As a result, the risk of broken redistribution layer (RDL) due to bowing is reduced or eliminated. In addition, the compressive dielectric layer, which is formed between the conductive TSV columns and surrounding molding compound, improves the adhesion between the conductive TSV columns and the molding compound. Consequently, the reliability of the die package is improved.

Abstract: A chip package may include: a first die; at least one second die disposed over the first die; and a lid disposed over lateral portions of the first die and at least partially surrounding the at least one second die, the lid having inclined sidewalls spaced apart from and facing the at least one second die.

Abstract: A method for forming through vias comprises the steps of forming a dielectric layer over a package and forming an RDL over the dielectric layer, wherein forming the RDL includes the steps of forming a seed layer, forming a first patterned mask over the seed layer, and performing a first metal plating. The method further includes forming through vias on top of a first portion of the RDL, wherein forming the through vias includes forming a second patterned mask over the seed layer and the RDL, and performing a second metal plating. The method further includes attaching a chip to a second portion of the RDL, and encapsulating the chip and the through vias in an encapsulating material.

Abstract: Integrated circuit packages and methods of forming same are provided. A method includes attaching a first die and a second die to a carrier, the first die having a first contact pad, the second die having a second contact pad, the first contact pad and the second contact pad having different structures. A release layer is formed over the first die and the second die. An encapsulant is injected between the carrier and the release layer. One or more redistribution layers (RDLs) are formed over the first die, the second die and the encapsulant, the first contact pad and the second contact pad being in electrical contact with the one or more RDLs.

Abstract: An example method includes providing a packaging device includes a substrate having an integrated circuit die mounting region. A plurality of microstructures, each including an outer insulating layer over a conductive material, are disposed proximate a side of the integrated circuit die mounting region. An underfill material is disposed between the substrate and the integrated circuit die, the microstructures preventing spread of the underfill. In another example method, a via can be formed in a substrate and the substrate etched to form a bump or pillar from the via. An insulating material can be formed over the bump or pillar. In another example method, a photoresist deposited over a seed layer and patterned to form openings. A conductive material is plated in the openings, forming a plurality of pillars or bumps. The photoresist and exposed seed layer are removed. The conductive material is oxidized to form an insulating material.

Abstract: A semiconductor device includes a semiconductor substrate, a conductive pad on the semiconductor substrate, and a first dielectric over the semiconductor substrate. The semiconductor device also includes a conductive layer disposed in the first dielectric and a second dielectric disposed on the conductive layer. In the semiconductor device, at least a portion of the conductive layer is exposed from the first dielectric and second dielectric. The semiconductor device further includes a conductive trace partially over the second dielectric and in contact with the exposed portion of the conductive layer. In the semiconductor device, the conductive trace is connected to the conductive pad at one end.

Abstract: A method for forming through vias comprises the steps of forming a dielectric layer over a package and forming an RDL over the dielectric layer, wherein forming the RDL includes the steps of forming a seed layer, forming a first patterned mask over the seed layer, and performing a first metal plating. The method further includes forming through vias on top of a first portion of the RDL, wherein forming the through vias includes forming a second patterned mask over the seed layer and the RDL, and performing a second metal plating. The method further includes attaching a chip to a second portion of the RDL, and encapsulating the chip and the through vias in an encapsulating material.

Abstract: An example packaging device includes a substrate having an integrated circuit die mounting region disposed thereon. A plurality of microstructures are disposed proximate a side of the integrated circuit die mounting region. The plurality of microstructures each include an outer insulating layer over a conductive material. An example packaged semiconductor device includes a substrate having an integrated circuit die mounting region disposed thereon. A plurality of columnar microstructures are disposed on the substrate perpendicular to a major surface of the substrate and proximate a side of the integrated circuit die mounting region. An underfill material is disposed between the substrate and the integrated circuit die.

Abstract: Various embodiments of mechanisms for forming a die package using a compressive dielectric layer to contact and to surround through substrate vias (TSVs) in the die package are provided. The compressive dielectric layer reduces or eliminates bowing of the die package. As a result, the risk of broken redistribution layer (RDL) due to bowing is reduced or eliminated. In addition, the compressive dielectric layer, which is formed between the conductive TSV columns and surrounding molding compound, improves the adhesion between the conductive TSV columns and the molding compound. Consequently, the reliability of the die package is improved.

Abstract: Various embodiments of mechanisms for forming a die package using a compressive dielectric layer to contact and to surround through substrate vias (TSVs) in the die package are provided. The compressive dielectric layer reduces or eliminates bowing of the die package. As a result, the risk of broken redistribution layer (RDL) due to bowing is reduced or eliminated. In addition, the compressive dielectric layer, which is formed between the conductive TSV columns and surrounding molding compound, improves the adhesion between the conductive TSV columns and the molding compound. Consequently, the reliability of the die package is improved.

Abstract: Packaging devices, packaged semiconductor devices, and packaging methods are disclosed. In some embodiments, a packaging device includes a substrate having an integrated circuit die mounting region disposed thereon. Microstructures are disposed proximate a side of the integrated circuit die mounting region of the substrate.

Abstract: A chip package may include: a first die; at least one second die disposed over the first die; and a lid disposed over lateral portions of the first die and at least partially surrounding the at least one second die, the lid having inclined sidewalls spaced apart from and facing the at least one second die.

Abstract: Methods of packaging semiconductor devices and structures thereof are disclosed. In one embodiment, a method of packaging a semiconductor device includes providing a substrate, and adhering a first semiconductor device. Chip stacks are formed by providing a plurality of semiconductor devices and bonding them to the substrate and the first semiconductor device. At least one of the provided semiconductor devices is physically connected to both the substrate and the first semiconductor device it is stack on. Other semiconductor devices may stacked by forming conductive channels in the first semiconductor device, and placing the other semiconductor devices in physical contact with the first semiconductor device and the conductive channels.

Abstract: Various embodiments of mechanisms for forming a die package using through sidewall vias (TsVs), which are formed by sawing through substrate via (TSV) in half, at edges of dies described enable various semiconductor dies and passive components be electrically connected to achieve targeted electrical performance. Redistribution structures with redistribution layers (RDLs) are used along with the TsVs to enable the electrical connections. Since the TsVs are away from the device regions, the device regions do not suffer from the stress caused by the TSV formation. In addition, electrical connections between upper and lower dies by the TsVs increases the efficiency of the area utilization of the die package.

Abstract: Packaging methods and packaged devices are disclosed. In one embodiment, a method of packaging a semiconductor device includes forming a first redistribution layer (RDL) over a carrier, and forming a plurality of through assembly vias (TAVs) over the first RDL. An integrated circuit die is coupled over the first RDL, and a molding compound is formed over the first RDL, the TAVs, and the integrated circuit die. A second RDL is formed over the molding compound, the TAVs, and the integrated circuit die.

Abstract: Various embodiments of mechanisms for forming a die package using through sidewall vias (TsVs), which are formed by sawing through substrate via (TSV) in half, at edges of dies described enable various semiconductor dies and passive components be electrically connected to achieve targeted electrical performance. Redistribution structures with redistribution layers (RDLs) are used along with the TsVs to enable the electrical connections. Since the TsVs are away from the device regions, the device regions do not suffer from the stress caused by the TSV formation. In addition, electrical connections between upper and lower dies by the TsVs increases the efficiency of the area utilization of the die package.

Abstract: Packaging methods and packaged devices are disclosed. In one embodiment, a method of packaging a semiconductor device includes forming a first redistribution layer (RDL) over a carrier, and forming a plurality of through assembly vias (TAVs) over the first RDL. An integrated circuit die is coupled over the first RDL, and a molding compound is formed over the first RDL, the TAVs, and the integrated circuit die. A second RDL is formed over the molding compound, the TAVs, and the integrated circuit die.