Abstract: A system and method for providing a post-passivation opening and undercontact metallization is provided. An embodiment comprises an opening through the post-passivation which has a first dimension longer than a second dimension, wherein the first dimension is aligned perpendicular to a chip's direction of coefficient of thermal expansion mismatch. By shaping and aligning the opening through the post-passivation layer in this fashion, the post-passivation layer helps to shield the underlying layers from stresses generated from mismatches of the materials' coefficient of thermal expansion.

Abstract: Embodiments of the present disclosure include a semiconductor device, a package and methods of forming a semiconductor device and a package. An embodiment is a semiconductor device including a molding material over a first substrate with a first opening having a first width in the molding material. The semiconductor device further includes a second opening having a second width in the molding material with the second width being greater than the first width. A first connector is in the first opening and a second connector is in the second opening.

Abstract: A system and method for providing a post-passivation and underbump metallization is provided. An embodiment comprises a post-passivation layer that is larger than an overlying underbump metallization. The post-passivation layer extending beyond the underbump metallization shields the underlying layers from stresses generated from mismatches of the materials' coefficient of thermal expansion.

Abstract: Various packages and methods of forming packages are disclosed. In an embodiment, a package includes a hybrid encapsulant encapsulating a chip attached to a substrate. The hybrid encapsulant comprises a first molding compound and a second molding compound that has a different composition than the first molding compound. In another embodiment, a package includes an encapsulant encapsulating a chip attached to a substrate. A surface of the chip is exposed through the encapsulant. The encapsulant comprises a recess in a surface of a first molding compound proximate the surface of the chip. A thermal interface material is on the surface of the chip and in the recess, and a lid is attached to the thermal interface material.

Abstract: Disclosed herein is a device comprising a first package having a first side with a plurality of connectors disposed thereon and a second package mounted on the first package by the connectors. A molding compound is disposed on the first side of the first package and between the first package and the second package. A plurality of stress relief structures (SRSs) are disposed in the molding compound, the plurality of SRSs each comprising a cavity free of metal in the molding compound and spaced apart from each of the plurality of connectors.

Abstract: Disclosed herein is a device comprising a first package having a first side with a plurality of connectors disposed thereon and a second package mounted on the first package by the connectors. A molding compound is disposed on the first side of the first package and between the first package and the second package. A plurality of stress relief structures (SRSs) are disposed in the molding compound, the plurality of SRSs each comprising a cavity free of metal in the molding compound and spaced apart from each of the plurality of connectors.

Abstract: Embodiments of the present disclosure include a semiconductor device, a package and methods of forming a semiconductor device and a package. An embodiment is a semiconductor device including a molding material over a first substrate with a first opening having a first width in the molding material. The semiconductor device further includes a second opening having a second width in the molding material with the second width being greater than the first width. A first connector is in the first opening and a second connector is in the second opening.

Abstract: Embodiments of the present disclosure include a semiconductor device, a package and methods of forming a semiconductor device and a package. An embodiment is a semiconductor device including a molding material over a first substrate with a first opening having a first width in the molding material. The semiconductor device further includes a second opening having a second width in the molding material with the second width being greater than the first width. A first connector is in the first opening and a second connector is in the second opening.

Abstract: Disclosed herein is a device comprising a first package having a first side with a plurality of connectors disposed thereon and a second package mounted on the first package by the connectors. A molding compound is disposed on the first side of the first package and between the first package and the second package. A plurality of stress relief structures (SRSs) are disposed in the molding compound, the plurality of SRSs each comprising a cavity free of metal in the molding compound and spaced apart from each of the plurality of connectors.

Abstract: A system and method for providing a post-passivation and underbump metallization is provided. An embodiment comprises a post-passivation layer that is larger than an overlying underbump metallization. The post-passivation layer extending beyond the underbump metallization shields the underlying layers from stresses generated from mismatches of the materials' coefficient of thermal expansion.

Abstract: A system and method for providing a post-passivation and underbump metallization is provided. An embodiment comprises a post-passivation layer that is larger than an overlying underbump metallization. The post-passivation layer extending beyond the underbump metallization shields the underlying layers from stresses generated from mismatches of the materials' coefficient of thermal expansion.

Abstract: A package on packaging structure provides for improved thermal conduction and mechanical strength by the introduction of a sold thermal coupler between the first and second packages. The first package has a first substrate and through vias through the first substrate. A first set of conductive elements is aligned with and coupled to the through vias of the first substrate. A solid thermal coupler is coupled to the first set of conductive elements and to a die of the second package. A second set of conductive elements is coupled to the die and a bottom substrate is coupled to the second set of conductive elements. The thermal coupler may be, e.g., an interposer, a heat spreader, or a thermal conductive layer.

Abstract: Between an adhesive surface of a heat spreader lid and a top surface of a semiconductor package, in addition to a spreader adhesive layer, several warpage control adhesive layers are also provided. The warpage control adhesive layers are disposed on corner areas of the adhesive surface of the heat spreader lid to reduce high temperature warpage of the semiconductor device package.

Abstract: A three dimensional integrated circuit (3DIC) includes a first substrate and a heat spreading structure embedded in the first substrate. The 3DIC further includes a die electrically connected to the first substrate, wherein the die is thermally connected to the heat spreading structure. The 3DIC further includes a plurality of memory units on the die, wherein the die is between the plurality of memory units and the first substrate, and the plurality of memory units is thermally connected to the heat spreading structure by the die. The 3DIC further includes an external cooling unit on the plurality of memory units, wherein the plurality of memory units is between the die and the external cooling unit, and the die is thermally connected to the external cooling unit by the plurality of memory units.

Abstract: Various packages and methods of forming packages are disclosed. In an embodiment, a package includes a hybrid encapsulant encapsulating a chip attached to a substrate. The hybrid encapsulant comprises a first molding compound and a second molding compound that has a different composition than the first molding compound. In another embodiment, a package includes an encapsulant encapsulating a chip attached to a substrate. A surface of the chip is exposed through the encapsulant. The encapsulant comprises a recess in a surface of a first molding compound proximate the surface of the chip. A thermal interface material is on the surface of the chip and in the recess, and a lid is attached to the thermal interface material.

Abstract: Disclosed herein is a device comprising a first package having a first side with a plurality of connectors disposed thereon and a second package mounted on the first package by the connectors. A molding compound is disposed on the first side of the first package and between the first package and the second package. A plurality of stress relief structures (SRSs) are disposed in the molding compound, the plurality of SRSs each comprising a cavity free of metal in the molding compound and spaced apart from each of the plurality of connectors.

Abstract: Embodiments of the present disclosure include a semiconductor device, a package and methods of forming a semiconductor device and a package. An embodiment is a semiconductor device including a molding material over a first substrate with a first opening having a first width in the molding material. The semiconductor device further includes a second opening having a second width in the molding material with the second width being greater than the first width. A first connector is in the first opening and a second connector is in the second opening.

Abstract: A package on packaging structure provides for improved thermal conduction and mechanical strength by the introduction of a sold thermal coupler between the first and second packages. The first package has a first substrate and through vias through the first substrate. A first set of conductive elements is aligned with and coupled to the through vias of the first substrate. A solid thermal coupler is coupled to the first set of conductive elements and to a die of the second package. A second set of conductive elements is coupled to the die and a bottom substrate is coupled to the second set of conductive elements. The thermal coupler may be, e.g., an interposer, a heat spreader, or a thermal conductive layer.

Abstract: Various packages and methods of forming packages are disclosed. In an embodiment, a package includes a hybrid encapsulant encapsulating a chip attached to a substrate. The hybrid encapsulant comprises a first molding compound and a second molding compound that has a different composition than the first molding compound. In another embodiment, a package includes an encapsulant encapsulating a chip attached to a substrate. A surface of the chip is exposed through the encapsulant. The encapsulant comprises a recess in a surface of a first molding compound proximate the surface of the chip. A thermal interface material is on the surface of the chip and in the recess, and a lid is attached to the thermal interface material.

Abstract: Various packages and methods are disclosed. A package according to an embodiment includes a substrate, a chip attached to a surface of the substrate with electrical connectors, a molding compound on the surface of the substrate and around the chip, an adhesive on a surface of the chip that is distal from the surface of the substrate, and a lid on the adhesive. In an embodiment, a region between the molding compound and the lid at a corner of the lid is free from the adhesive. In another embodiment, the lid has a recess in a surface of the lid facing the surface of the molding compound.