The present disclosure provides a manufacturing method of a die-stack structure including follow steps. A first wafer including a first die is provided, wherein the first die includes a first substrate material layer, a first interconnect structure, and a first pad, and the first interconnect structure and the first pad are formed on the first substrate material layer in order, and the first substrate material layer has a first contact conductor disposed therein. a first contact conductor is disposed in the first substrate material layer. A second wafer including a second die is provided, wherein the second die includes a second substrate material layer, a second interconnect structure, and a second pad, and the second interconnect structure and the second pad are formed on the second substrate material layer in order, and the second substrate material layer has a second contact conductor disposed therein. A portion of the first substrate material layer is removed to form a first substrate, wherein the first contact conductor is exposed to a surface of the first substrate away from the first interconnect structure. The second wafer is covered on the first substrate such that the first contact conductor is directly physically in contact with the second pad.

A method of forming a chip package is provided. The method includes providing a malleable carrier with a layer of an electrically conductive material formed thereon, and positive fitting the malleable carrier to a chip to at least partially enclose the chip with the malleable carrier. The layer at least partially physically contacts the chip, such that the layer electrically contacts a chip contact of the chip. The layer forms a redistribution layer.

Provided is a printed wiring board comprising: a substrate; a conductive layer including a land and a wiring and formed on a surface of the substrate, the wiring having a width smaller than the land and drawn from the land; and an insulating layer formed on the conductive layer. The insulating layer has an opening corresponding to a position of the land, and an edge of the opening runs above the land and above one of edges in a width direction of the wiring.

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.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between vertically stacked devices and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise at least one memory device mounted over a logic device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the memory device and the logic device. The thermally conductive layer includes a structure configured to transfer the thermal energy across a horizontal plane. The thermal-insulator interposer includes a structure configured to reduce heat transfer between the logic device and the memory device.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between vertically stacked devices and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise at least one memory device mounted over a logic device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the memory device and the logic device. The thermally conductive layer includes a structure configured to transfer the thermal energy across a horizontal plane. The thermal-insulator interposer includes a structure configured to reduce heat transfer between the logic device and the memory device.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between vertically stacked devices and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise at least one memory device mounted over a logic device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the memory device and the logic device. The thermally conductive layer includes a structure configured to transfer the thermal energy across a horizontal plane. The thermal-insulator interposer includes a structure configured to reduce heat transfer between the logic device and the memory device.

Semiconductor assemblies including thermal management configurations for reducing heat transfer between vertically stacked devices and associated systems and methods are disclosed herein. In some embodiments, the semiconductor assemblies comprise at least one memory device mounted over a logic device with a thermally conductive layer, a thermal-insulator interposer, or a combination thereof disposed between the memory device and the logic device. The thermally conductive layer includes a structure configured to transfer the thermal energy across a horizontal plane. The thermal-insulator interposer includes a structure configured to reduce heat transfer between the logic device and the memory device.

Electrical interconnect bridge technology is disclosed. An electrical interconnect bridge can include a bridge substrate formed of a mold compound material. The electrical interconnect bridge can also include a plurality of routing layers within the bridge substrate, each routing layer having a plurality of fine line and space (FLS) traces. In addition, the electrical interconnect bridge can include a via extending through the substrate and electrically coupling at least one of the FLS traces in one of the routing layers to at least one of the FLS traces in another of the routing layers.

A primary-side electrode and a secondary-side electrode of a power device are disposed so as to straddle plural separate primary and secondary wires in a first conductive layer, a second conductive layer includes plural separate primary and secondary wires, an insulating part is disposed in a first insulating layer in a region between the primary and secondary wires and directly below the power device, an intralayer insulating part is disposed in the second conductive layer in a region between the primary and secondary wires and directly below the power device, and a via that connects the primary wire in the first conductive layer and the primary wire in the second conductive layer and connects the secondary wire in the first conductive layer and the secondary wire in the second conductive layer is disposed in the first insulating layer directly below the primary-side and secondary-side electrodes of the power device.