Methods/structures of joining package structures are described. Those methods/structures may include a die disposed on a surface of a substrate, an interconnect bridge embedded in the substrate, and at least one vertical interconnect structure disposed through a portion of the interconnect bridge, wherein the at least one vertical interconnect structure is electrically and physically coupled to the die.

A system includes a first die having a first side with first die-to-die circuitry and first input output circuitry. The system also includes a second die comprising a second side with second die-to-die circuitry and second input output circuitry. The first and second sides are adjacent to each other in the electronic package device. The system also includes a semiconductor interconnect including multiple connections to interconnect the first and second die-to-die circuitries. The semiconductor interconnect also includes multiple through-silicon-vias to transmit data to or from the first and second input output circuitries through the semiconductor bridge.

Various embodiments relate to a semiconductor package. The semiconductor package includes a first die. The first die includes a first bridge interconnect region. The semiconductor package further includes a second die. The second die includes a second bridge interconnect region. The semiconductor package includes a bridge die. The bridge die includes a first contact area to connect to the first bridge interconnect region and a second contact area to connect to the second bridge interconnect region. In the semiconductor package, the first bridge interconnect region is larger than the second bridge interconnect region. Additionally, each of the first bridge interconnect region and the second bridge interconnect region include a plurality of conductive bumps. An average pitch between adjacent bumps of the first bridge interconnect region is larger than an average pitch between adjacent bumps of the second bridge interconnect region.

A multi-chip package includes a substrate (110) having a first side (111), an opposing second side (112), and a third side (213) that extends from the first side to the second side, a first die (120) attached to the first side of the substrate and a second die (130) attached to the first side of the substrate, and a bridge (140) adjacent to the third side of the substrate and attached to the first die and to the second die. No portion of the substrate is underneath the bridge. The bridge creates a connection between the first die and the second die. Alternatively, the bridge may be disposed in a cavity (615, 915) in the substrate or between the substrate and a die layer (750). The bridge may constitute an active die and may be attached to the substrate using wirebonds (241, 841, 1141, 1541).

In an embodiment, a structure includes a core substrate, a redistribution structure coupled, the redistribution structure including a plurality of redistribution layers, the plurality of redistribution layers comprising a dielectric layer and a metallization layer, a first local interconnect component embedded in a first redistribution layer of the plurality of redistribution layers, the first local interconnect component comprising conductive connectors, the conductive connectors being bonded to a metallization pattern of the first redistribution layer, the dielectric layer of the first redistribution layer encapsulating the first local interconnect component, a first integrated circuit die coupled to the redistribution structure, a second integrated circuit die coupled to the redistribution structure, an interconnect structure of the first local interconnect component electrically coupling the first integrated circuit die to the second integrated circuit die, and a set of conductive connectors coupled to a second side of the core substrate.

An integrated circuit (IC) chip package and a method of fabricating the same are disclosed. The IC chip package includes first and second interconnect substrates on a same surface level, first and second integrated circuit (IC) chips disposed on the first and second interconnect substrates, respectively, an IC chip coupler disposed on the first and second interconnect substrates and configured to provide a signal transmission path between the first and second IC chips, and a redistribution structure disposed on the first and second IC chips and the IC chip coupler. The IC chip coupler includes a first coupler region that overlaps with the first interconnect substrate, a second coupler region that overlaps with the second interconnect substrate, a third coupler region that overlaps with a space between the first and second interconnect substrates, and an interconnect structure with conductive lines and conductive vias.

Embodiments include semiconductor packages. A semiconductor package includes a first patch and a second patch on an interposer. The semiconductor package also includes a first substrate in the first patch, and a second substrate in the second patch. The semiconductor package further includes an encapsulation layer over and around the first and second patches, a plurality of build-up layers on the first patch, the second patch, and the encapsulation layer, and a plurality of dies and a bridge on the build-up layers. The bridge may be communicatively coupled with the first substrate of the first patch and the second substrate of the second patch. The bridge may be an embedded multi-die interconnect bridge (EMIB). The first and second substrates may be EMIBs and/or high-density packaging (HDP) substrates. The bridge may be positioned between two dies, and over an edge of the first patch and an edge of the second patch.

Embodiments of the present disclosure are directed towards techniques and configurations for layered interconnect structures for bridge interconnection in integrated circuit assemblies. In one embodiment, an apparatus may include a substrate and a bridge embedded in the substrate. The bridge may be configured to route electrical signals between two dies. An interconnect structure, electrically coupled with the bridge, may include a via structure including a first conductive material, a barrier layer including a second conductive material disposed on the via structure, and a solderable material including a third conductive material disposed on the barrier layer. The first conductive material, the second conductive material, and the third conductive material may have different chemical composition. Other embodiments may be described and/or claimed.

Embodiments include semiconductor packages and methods to form the semiconductor packages. A semiconductor package includes a bridge over a glass patch. The bridge is coupled to the glass patch with an adhesive layer. The semiconductor package also includes a high-density packaging (HDP) substrate over the bridge and the glass patch. The HDP substrate is conductively coupled to the glass patch with a plurality of through mold vias (TMVs). The semiconductor package further includes a plurality of dies over the HDP substrate, and a first encapsulation layer over the TMVs, the bridge, the adhesive layer, and the glass patch. The HDP substrate includes a plurality of conductive interconnects that conductively couple the dies to the bridge and glass patch. The bridge may be an embedded multi-die interconnect bridge (EMIB), where the EMIB is communicatively coupled to the dies, and the glass patch includes a plurality of through glass vias (TGVs).

A packaging technology to improve performance of an AI processing system resulting in an ultra-high bandwidth system. An IC package is provided which comprises: a substrate; a first die on the substrate, and a second die stacked over the first die. The first die can be a first logic die (e.g., a compute chip, CPU, GPU, etc.) while the second die can be a compute chiplet comprising ferroelectric or paraelectric logic. Both dies can include ferroelectric or paraelectric logic. The ferroelectric/paraelectric logic may include AND gates, OR gates, complex gates, majority, minority, and/or threshold gates, sequential logic, etc. The IC package can be in a 3D or 2.5D configuration that implements logic-on-logic stacking configuration. The 3D or 2.5D packaging configurations have chips or chiplets designed to have time distributed or spatially distributed processing. The logic of chips or chiplets is segregated so that one chip in a 3D or 2.5D stacking arrangement is hot at a time.