A semiconductor device includes a first chip and a second chip stacked on the first chip. The first chip includes a first substrate, a first upper pad on an upper surface of the first substrate, a first upper insulating layer surrounding a lower portion of the first upper pad and a sacrificial layer surrounding an upper portion of the first upper pad. The second chip includes a second substrate, a second upper pad on an upper surface of the second substrate and a second upper insulating layer surrounding the second upper pad, wherein a thickness of the second upper pad is less than a thickness of the first upper pad.

A printed structure comprises a device comprising device electrical contacts disposed on a common side of the device and a substrate non-native to the device comprising substrate electrical contacts disposed on a surface of the substrate. At least one of the substrate electrical contacts has a rounded shape. The device electrical contacts are in physical and electrical contact with corresponding substrate electrical contacts. The substrate electrical contacts can comprise a polymer core coated with a patterned contact electrical conductor on a surface of the polymer core. A method of making polymer cores comprising patterning a polymer on the substrate and reflowing the patterned polymer to form one or more rounded shapes of the polymer and coating and then patterning the one or more rounded shapes with a conductive material.

A semiconductor module according to the present disclosure includes a first substrate having a plurality of patterns having two or more different thickness, a first semiconductor device disposed on at least one or more patterns, a second substrate having a plurality of patterns having two or more different thickness. One or more of the plurality of patterns of the second substrate is placed on the first semiconductor device, a first terminal pattern and a second terminal pattern, each disposed between the first substrate and the second substrate, the first terminal pattern comprises a first upper terminal pattern and a first lower terminal pattern, and the second terminal pattern comprises a second upper terminal pattern and a second lower terminal pattern, and a conductive frame coupled to at least one of the first and the second terminal patterns.

An integrated circuit (IC) device comprises a substrate comprising a glass core. The glass core includes a first surface, a second surface opposite the first surface, and a sidewall between the first surface and the second surface. A build-up layer is on at least the first surface. A plurality of regions is on the sidewall. Each region comprises a cavity in the sidewall, wherein the cavity spans a first distance in a first direction from the first surface toward the second surface. In addition, the cavity comprises a concave surface having a first depth at the first surface and a second depth at the first distance, the second depth being less than the first depth.

Implementations generally relate to a multisided integrated circuit assembly. In some implementations, an assembly includes an integrated circuit (IC) chip having IC contact terminals. The assembly further includes surface interfaces coupled to the IC chip, where at least one first surface interface and at least one second surface interface of the surface interfaces are configured to couple to a motherboard. The assembly further includes surface contact terminals on the surface interfaces, where the surface contact terminals couple to the IC contact terminals, and where at least one subset of the surface contact terminals also couples to at least one subset of motherboard contact terminals on the motherboard.

A semiconductor package includes a die stack including a first semiconductor die having a first interconnect structure, and a second semiconductor die having a second interconnect structure direct bonding to the first interconnect structure of the first semiconductor die. The second interconnect structure includes connecting pads disposed in a peripheral region around the first semiconductor die. First connecting elements are disposed on the connecting pads, respectively. A substrate includes second connecting elements on a mounting surface of the substrate. The first connecting elements are electrically connected to the second connecting elements through an anisotropic conductive structure.

An offset interposer includes a land side including land-side ball-grid array (BGA) and a package-on-package (POP) side including a POP-side BGA. The land-side BGA includes two adjacent, spaced-apart land-side pads, and the POP-side BGA includes two adjacent, spaced-apart POP-side pads that are coupled to the respective two land-side BGA pads through the offset interposer. The land-side BGA is configured to interface with a first-level interconnect. The POP-side BGA is configured to interface with a POP substrate. Each of the two land-side pads has a different footprint than the respective two POP-side pads.

A method for direct bonding an electronic chip onto a substrate or another electronic chip, the method including: carrying out a hydrophilic treatment of a portion of, a surface of the electronic chip and of a portion of a surface of the substrate or of the other electronic chip; depositing an aqueous fluid on the portion of the surface of the substrate or of the second electronic chip; depositing the portion of the surface of the electronic chip on the aqueous fluid; drying the aqueous fluid until the portion of the surface of the electronic chip is rigidly connected to the portion of the surface of the substrate or of the other electronic chip: and during at least part of the drying of the aqueous fluid, emitting ultrasound into the aqueous fluid through the substrate or the other electronic chip.

An offset interposer includes a land side including land-side ball-grid array (BGA) and a package-on-package (POP) side including a POP-side BGA. The land-side BGA includes two adjacent, spaced-apart land-side pads, and the POP-side BGA includes two adjacent, spaced-apart POP-side pads that are coupled to the respective two land-side BGA pads through the offset interposer. The land-side BGA is configured to interface with a first-level interconnect. The POP-side BGA is configured to interface with a POP substrate. Each of the two land-side pads has a different footprint than the respective two POP-side pads.

A multi-grooved interposer includes an interposer substrate containing multiple parallel grooves laterally extending along a first direction and laterally spaced among one another along a second direction, and multiple conductive strips. The multiple parallel grooves are recessed from front side surfaces of the multi-grooved interposer in a third direction toward a back side surface of the multi-grooved interposer. The multiple conductive strips continuously extend across recessed surfaces in the multiple parallel grooves and the front side surfaces along the second direction with an undulating surface profile to provide electrically conductive paths across the multiple parallel grooves. Each of the multiple parallel grooves is configured to receive an edge of a respective semiconductor chip.