A method is provided. The method includes attaching a bridge layer to a first substrate. The method also includes forming a first connector, the first connector electrically connecting the bridge layer to the first substrate. The method also includes coupling a first die to the bridge layer and the first substrate, and coupling a second die to the bridge layer.

An apparatus is provided which comprises: a first die having a first surface and a second surface, the first die comprising: a first layer formed on the first surface of the first die, and a second layer formed on the second surface of the first die; a second die coupled to the first layer; and a plurality of structures to couple the apparatus to an external component, wherein the plurality of structures is coupled to the second layer.

Discussed generally herein are devices that include high density interconnects between dice and techniques for making and using those devices. In one or more embodiments a device can include a bumpless buildup layer (BBUL) substrate including a first die at least partially embedded in the BBUL substrate, the first die including a first plurality of high density interconnect pads. A second die can be at least partially embedded in the BRIM substrate, the second die including a second plurality of high density interconnect pads. A high density interconnect element can be embedded in the BBUL substrate, the high density interconnect element including a third plurality of high density interconnect pads electrically coupled to the first and second plurality of high density interconnect pads.

In a multi-chip module (MCM), a super chip (110N) is attached to multiple plain chips (110F super and plain chips can be any chips). The super chip is positioned above the wiring board (WB) but below at least some of plain chips (110F). The plain chips overlap the super chip. Further, the plain chips' low speed IOs can be connected to the WB by long direct connections such as bond wires (e.g. BVAs) or solder stacks; such connections can be placed side by side with the super chip. Such connections can be long, so the super chip is not required to be thin. Also, if through-substrate vias (TSVs) are omitted, the manufacturing yield is high and the manufacturing cost is low. Other structures are provided that combine the short and long direct connections to obtain desired physical and electrical properties.

An optoelectronic assembly and methods of fabrication thereof are provided. The assembly includes a mold compound; a photonic integrated circuit (PIC) embedded in the mold compound, that has a face exposed from the mold compound in a first plane; an interposer embedded in the mold compound, that has a face exposed from the mold compound in the first plane (i.e., co-planar with the exposed face of the PIC); and an electrical integrated circuit (EIC) coupled to the exposed face of the PIC and the exposed face of the interposer, that establishes bridging electrical connections between the PIC and the interposer.

Embodiments of the present disclosure are directed towards package assemblies, as well as methods for forming package assemblies and systems incorporating package assemblies. A package assembly may include a substrate including a plurality of build-up layers, such as bumpless build-up layer (BBUL). In various embodiments, electrical routing features may be disposed on an outer surface of the substrate. In various embodiments, a primary logic die and a second die or capacitor may be embedded in the plurality of build-up layers. In various embodiments, an electrical path may be defined in the plurality of build-up layers to route electrical power or a ground signal between the second die or capacitor and the electrical routing features, bypassing the primary logic die.

Discussed generally herein are devices that include high density interconnects between dice and techniques for making and using those devices. In one or more embodiments a device can include a bumpless buildup layer (BBUL) substrate including a first die at least partially embedded in the BBUL substrate, the first die including a first plurality of high density interconnect pads. A second die can be at least partially embedded in the BBUL substrate, the second die including a second plurality of high density interconnect pads. A high density interconnect element can be embedded in the BBUL substrate, the high density interconnect element including a third plurality of high density interconnect pads electrically coupled to the first and second plurality of high density interconnect pads.

Quantum computing assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a quantum computing assembly may include a plurality of dies electrically coupled to a package substrate, and lateral interconnects between different dies of the plurality of dies, wherein the lateral interconnects include a superconductor, and at least one of the dies of the plurality of dies includes quantum processing circuitry.

Discussed generally herein are devices that include high density interconnects between dice and techniques for making and using those devices. In one or more embodiments a device can include a bumpless buildup layer (BBUL) substrate including a first die at least partially embedded in the BBUL substrate, the first die including a first plurality of high density interconnect pads. A second die can be at least partially embedded in the BBUL substrate, the second die including a second plurality of high density interconnect pads. A high density interconnect element can be embedded in the BBUL substrate, the high density interconnect element including a third plurality of high density interconnect pads electrically coupled to the first and second plurality of high density interconnect pads.

In a semiconductor device, a first semiconductor chip having a main surface provided with a first terminal group including terminals, and a rear face mounted on a surface of a support. A second semiconductor chip has a main surface provided with a second terminal group including terminals, the main surface of the second semiconductor chip facing the main surface of the first semiconductor chip, and each of the terminals in the second terminal group being connected to a corresponding one of the terminals in the first terminal group of the first semiconductor chip. The first semiconductor chip is connected to an external terminal of the semiconductor device via a conductor containing a single metal.