Stacked semiconductor die assemblies having memory dies stacked between partitioned logic dies and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a first logic die, a second logic die, and a thermally conductive casing defining an enclosure. The stack of memory dies can be disposed within the enclosure and between the first and second logic dies.

A method for mounting an electrical component on a substrate is disclosed. According to the method, joining is simplified using a cover, or hood, that includes a contact structure on an inner side of the hood, wherein when the hood is mounted, the contact structure is joined to the underlying structure at different joining levels simultaneously using an additional material. Moreover, a joining pressure, e.g., for diffusion or sintered bonds for electrical contacts, can be applied using such a hood.

A disclosed semiconductor structure may include an interposer, a first semiconductor die electrically coupled to the interposer, a packaging substrate electrically coupled to the interposer, and a capping layer covering one or more of a first surface of the first semiconductor die and a second surface of the packaging substrate. The capping layer may be formed over respective surfaces of each of the first semiconductor die and the packaging substrate. In certain embodiments, the capping layer may be formed only on the first surface of the first semiconductor die and not formed over the package substrate. In further embodiments, the semiconductor structure may include a second semiconductor die, such that the capping layer covers a surface of only one of the first semiconductor die and the second semiconductor die. The semiconductor structure may include a molding compound die frame that is partially or completely covered by the capping layer.

Stacked semiconductor die assemblies having memory dies stacked between partitioned logic dies and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a first logic die, a second logic die, and a thermally conductive casing defining an enclosure. The stack of memory dies can be disposed within the enclosure and between the first and second logic dies.

Stacked semiconductor die assemblies having memory dies stacked between partitioned logic dies and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a first logic die, a second logic die, and a thermally conductive casing defining an enclosure. The stack of memory dies can be disposed within the enclosure and between the first and second logic dies.

Stacked semiconductor die assemblies having memory dies stacked between partitioned logic dies and associated systems and methods are disclosed herein. In one embodiment, a semiconductor die assembly can include a first logic die, a second logic die, and a thermally conductive casing defining an enclosure. The stack of memory dies can be disposed within the enclosure and between the first and second logic dies.

Die (110) are attached to an interposer (420), and the interposer/die assembly is placed into a lid cavity (510). The lid (210) is attached to the top of the assembly, possibly to the encapsulant (474) at the top. The lid's legs (520) surround the cavity and extend down below the top surface of the interposer's substrate (420S), possibly to the level of the bottom surface of the substrate or lower. The legs (520) may or may not be attached to the interposer/die assembly. In fabrication, the interposer wafer (420SW) has trenches (478) which receive the lid's legs during the lid placement. The interposer wafer is later thinned to remove the interposer wafer portion below the legs and to dice the interposer wafer. The thinning process also exposes, on the bottom, conductive vias (450) passing through the interposer substrate. Other features are also provided.

A printed circuit board includes: a printed wiring board including an insulating layer wherein a recessed part is provided on a top surface of the insulating layer, and a printed conductor provided inside the recessed part; a bare chip part mounted in the recessed part and electrically connected to the printed conductor; an electronic part mounted on the top surface of the printed wiring board other than the recessed part; and a cap fixed to the top surface of the printed wiring board and hollow-sealing the bare chip part mounted in the recessed part, wherein using a height of the top surface of the printed wiring board as a reference, a height of a top surface of the cap is equal to or below a maximum height of a top surface of the electronic part.

A semiconductor package may include a first wiring structure including a plurality of first redistribution patterns and a plurality of first redistribution insulating layers, a second wiring structure on the first wiring structure and including a plurality of second redistribution patterns and a plurality of second redistribution insulating layers, a semiconductor chip between the first wiring structure and the second wiring structure, an expanded layer including a plurality of connection structures electrically connecting the first wiring structure and the second wiring structure to each other and an encapsulant surrounding the plurality of connection structures and the semiconductor chip, a ceramic shield layer between the expanded layer and the second wiring structure, and a plurality of via structures penetrating the ceramic shield layer and electrically connecting the plurality of connection structures and the plurality of second redistribution patterns to each other.

A method for mounting an electrical component on a substrate is disclosed. According to the method, joining is simplified using a cover, or hood, that includes a contact structure on an inner side of the hood, wherein when the hood is mounted, the contact structure is joined to the underlying structure at different joining levels simultaneously using an additional material. Moreover, a joining pressure, e.g., for diffusion or sintered bonds for electrical contacts, can be applied using such a hood.