A die stack assembly includes first and second power semiconductor device dice. The first die has a P type peripheral edge separation structure that extends from the top planar semiconductor surface of the first die all the way to the bottom planar semiconductor surface of the die, and that is doped at least in part with aluminum. The backside of the first die is mounted to the backside of the second die. A metal feature that is not covered with passivation, and that can serve as a bonding pad, is disposed on part of the peripheral edge separation structure. A metal member (for example, a bond wire or metal clip) contacts the metal feature such that an electrical connection is established from the metal member, through the metal feature, through the peripheral edge separation structure of the first die, and to an electrode of the second die.

A laminated chip includes: semiconductor chips that are laminated; and multiple types of adhesive insulating resin films that include mutually different characteristics and that are filled between the semiconductor chips, wherein the multiple types of the adhesive insulating resin films are arranged in a chip plane direction, depending on a demand characteristic for each region in a chip plane.

A laminated chip includes: semiconductor chips that are laminated; and multiple types of adhesive insulating resin films that include mutually different characteristics and that are filled between the semiconductor chips, wherein the multiple types of the adhesive insulating resin films are arranged in a chip plane direction, depending on a demand characteristic for each region in a chip plane.

An apparatus is provided which comprises: a device surface, wherein the device surface comprises an array of solder contacts, a substrate surface, wherein the substrate surface comprises an array of pads, the array of solder contacts coupled with the array of pads, and a formation of epoxy coupled with the device surface and the substrate surface, wherein the formation of epoxy is entirely within an area of the array of solder contacts. Other embodiments are also disclosed and claimed.

A wafer level package includes a wafer, a lead disposed of the wafer for connecting the wafer to an electrical circuit, and a core disposed of the lead. In some embodiments, the lead disposed of the wafer is a copper pillar, and the core is plated onto the copper pillar. In some embodiments, the core is polymer screen-plated onto the lead. In some embodiments, the core extends between at least approximately thirty-five micrometers (35 m) and fifty micrometers (50 m) from the lead. In some embodiments, the core covers between at least approximately one-third () and one-half () of the surface area of the lead. In some embodiments, the core comprises a stud-shape extending from the lead. In some embodiments, the core extends perpendicularly across the lead. In some embodiments, the core extends longitudinally along the lead. Further, a portion of the core can extend perpendicularly from a longitudinal core.

A semiconductor package includes; a substrate including a first insulating layer and a first conductive pattern in the first insulating layer, a first semiconductor chip on the substrate, an interposer spaced apart from the first semiconductor chip in a direction perpendicular to an upper surface of the substrate and including a second insulating layer and a second conductive pattern in the second insulating layer, a first element between the first semiconductor chip and the interposer, a connection member between the substrate and the interposer, and a mold layer covering side surfaces of the first semiconductor chip and side surfaces of the first element.

A chip package on package structure includes a primary chip stack unit having pins insulated and spaced from each other on a first surface; a first bonding layer disposed on the first surface, where the first bonding layer includes bonding components insulated and spaced from each other, each bonding component includes a bonding part, and any two bonding parts are insulated and have a same cross-sectional area, and the bonding components are separately bonded to the pins; and secondary chip stack units, disposed on a surface of a side that is of the first bonding layer and that is away from the primary chip stack unit, where the secondary chip stack unit has micro bumps insulated and spaced from each other, and each of the micro bumps is bonded to one of the bonding components.

A package structure and a method of manufacturing a package structure are provided. The package structure includes a first substrate, a first electronic component, a second substrate and a second electronic component. The first electronic component is disposed over a first through hole of the first substrate. The first electronic component is electrically connected to a first patterned circuit layer of the first substrate through an extending portion of the first patterned circuit layer extending beyond a sidewall of the first through hole. The second electronic component is disposed over a second through hole of the second substrate. The second electronic component is electrically connected to a second patterned circuit layer of the second substrate through an inner extending portion of the second patterned circuit layer extending beyond a sidewall of the second through hole.

A method includes bonding a first package component over a second package component, dispensing a first underfill between the first package component and the second package component, and bonding a third package component over the second package component. A second underfill is between the third package component and the second package component. The first underfill and the second underfill are different types of underfills.

A method includes attaching a permeable plate to a metal lid, with the permeable plate including a metallic material, and dispensing a liquid-metal-comprising media to a first package component. The first package component is over and bonded to a second package component. The liquid-metal-comprising media includes a liquid metal therein. The method further includes attaching the metal lid to the second package component. During the attaching, the liquid-metal-comprising media migrates into the permeable plate to form a composite thermal interface material.