A packaged semiconductor device includes a substrate, a heat-generating component positioned on a surface of the substrate, an enclosure at least partially surrounding the substrate and the heat-generating component, and a thermal interface material disposed between the heat-generating component and the enclosure. The enclosure includes a cover portion having a convexly curved surface configured to apply a pressure to the thermal interface material. The pressure may be substantially uniform over the area of the thermal interface material, or may be higher at a center of the thermal interface material than at a periphery of the thermal interface material.

A package structure includes a semiconductor device, a circuit substrate and a heat dissipating lid. The semiconductor device includes a semiconductor die. The circuit substrate is bonded to and electrically coupled to the semiconductor device. The heat dissipating lid is bonded to the circuit substrate and thermally coupled to the semiconductor device, where the semiconductor device is located in a space confined by the heat dissipating lid and the circuit substrate. The heat dissipating lid includes a cover portion and a flange portion bonded to a periphery of the cover portion. The cover portion has a first surface and a second surface opposite to the first surface, where the cover portion includes a recess therein, the recess has an opening at the second surface, and a thickness of the recess is less than a thickness of the cover portion, where the recess is part of the space.

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 semiconductor package includes a substrate, a semiconductor die mounted on the substrate, and a heatsink over the semiconductor die. The heatsink includes a roof portion and at least one connecting portion extending between the roof portion and the substrate. The at least one connecting portion includes a connection lead mounted on a connection pad of the substrate. The connection pad includes a first portion and a second portion spaced apart from each other, which are configured to electrically couple to different voltage signals, respectively, for detecting heatsink floating.

A semiconductor package includes a package substrate. An interposer is disposed on the package substrate. The interposer in a semiconductor substrate, a wiring layer disposed on an upper surface of the semiconductor substrate and having a plurality of wirings therein, redistribution wiring pads disposed on the wiring layer and electrically connected to the wirings, bonding pads disposed on the redistribution wiring pads, and an insulation layer pattern disposed on the wiring layer and exposing at least a portion of the bonding pad, and first and second semiconductor devices disposed on the interposer. The first and second semiconductor devices are spaced apart from each other and are electrically connected to each other by at least one of the wirings.

Disclosed are semiconductor packages and methods of fabricating the same. The semiconductor package includes a redistribution substrate that includes a chip region and an edge region around the chip region, and a semiconductor chip on the chip region of the redistribution substrate. The redistribution substrate includes a plurality of dielectric layers that are vertically stacked, a plurality of redistribution patterns on the chip region and in each of the dielectric layers, and a redistribution test pattern on the edge region and at a level the same as a level of at least one of the redistribution patterns.

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.

The present invention provides a fan-out package structure and a method for manufacturing the same. The fan-out package structure includes at least one chip and at least one redistribution layer on a functional surface side of the chip, and the redistribution layer includes a dielectric layer and a metal wiring layer distributed within the dielectric layer. The fan-out package structure further includes at least one dummy wafer on the redistribution layer, and the dummy wafer is insulated from the chip and in contact with the metal wiring layer. By providing the dummy wafer on the redistribution layer and configuring the dummy wafer to connect to the metal wiring layer, the dummy wafer can not only function to support the structure and suppress the warpage, but also form a continuous heat dissipation channel, thereby improving thermal management capability of the fan-out package structure.

A package structure includes a circuit substrate, a semiconductor package, a thermal interface material, a lid structure and a heat dissipation structure. The semiconductor package is disposed on and electrically connected to the circuit substrate. The thermal interface material is disposed on the semiconductor package. The lid structure is disposed on the circuit substrate and surrounding the semiconductor package, wherein the lid structure comprises a supporting part that is partially covering and in physical contact with the thermal interface material. The heat dissipation structure is disposed on the lid structure and in physical contact with the supporting part of the lid structure.

Enhanced thermal energy transfer systems for semiconductor packages are provided. A thermally conductive member is disposed in the interstitial space between an upper surface of a semiconductor package and a lower surface of a thermal member. The thermally conductive member is disposed above a first portion of the upper surface of the semiconductor package having a relatively higher thermal energy output when the semiconductor package is operating. A thermal interface material is disposed in the interstitial space and a force applied to the thermal member. The thermally conductive member forms a relatively higher pressure region above the first portion of the semiconductor package and a relatively lower pressure region in other portions of the semiconductor package remote from the thermally conductive member. The increased pressure region proximate the thermally conductive member beneficially enhances the flow of thermal energy from the first portion of the semiconductor package to the thermal member.