A chip package structure is provided. The chip package structure includes a substrate. The chip package structure also includes a first chip structure and a second chip structure over the substrate. The chip package structure further includes an anti-warpage bar over a first portion of the first chip structure and over a second portion of the second chip structure. A width of the anti-warpage bar overlapping the second portion of the second chip structure is greater than a width of the anti-warpage bar overlapping the first portion of the first chip structure.

A patch structure of an integrated circuit package comprises a core having a first side facing downwards and a second side facing upwards. A first solder resist (SR) layer is formed on the first side of the core, wherein the first SR layer comprises a first layer interconnect (FLI) and has a first set of one or more microbumps thereon to bond to one or more logic die. A second solder resist (SR) layer is formed on the second side of the core, wherein the second SR layer has a second set of one or more microbumps thereon to bond with a substrate. One or more bridge dies includes a respective sets of bumps, wherein the one or more bridge dies is disposed flipped over within the core such that the respective sets of bumps face downward and connect to the first set of one or more microbumps in the FLI.

According to examples, an interconnect system for integrated circuits (ICs) may be fabricated by processing a substrate implanted with copper wells with a photoresist layer such that remaining portions of the photoresist layer expose portions of the copper wells; depositing a barrier layer over a top surface of the wafer, depositing a seed copper layer over the barrier layer; depositing a copper layer over the seed copper layer; planarizing the copper layer and portions of the barrier layer; depositing another copper layer over exposed portions of the substrate, the copper wells, and the interconnect cores; removing portions of the other copper layer between interconnects by processing the second copper layer with another photoresist layer; and removing remaining portions of the other photoresist layer on the interconnects.

A packaging semiconductor device, such as a fan-out Wafer-Level Packaging (FOWLP) device, is fabricated by providing a semiconductor device (20) having conductive patterns (22) disposed on a first surface and then forming, on the conductive patterns, photoresist islands (24) having a first predetermined shape defined by a first critical width dimension and a minimum height dimension so that a subsequently-formed dielectric polymer layer (26) surrounds but does not cover each photoresist island (24), thereby allowing each photoresist island to be selectively removed from the one or more conductive patterns to form one or more via openings (28) in the dielectric polymer layer such that each via opening has a second predetermined shape which matches at least part of the first predetermined shape of the photoresist islands.

A semiconductor package includes a semiconductor die having a device side, a conductive layer coupled to the device side, a conductive pillar coupled to the conductive layer, the conductive pillar having an upper portion and a base portion, the upper portion having a wider diameter than the base portion and the conductive pillar either having a mushroom shape or having sloped sides on the base portion extending away from the upper portion to the conductive layer, a polyimide layer coupled to the conductive layer and surrounding the conductive pillar, a solder layer coupled to the conductive pillar, wherein the polyimide layer does not extend between a top surface of the conductive pillar and the solder layer, and a conductive terminal coupled to the solder layer and exposed to a surface of the semiconductor package, the device side of the semiconductor die facing the conductive terminal.

In one instance, a semiconductor package includes a lead frame and a semiconductor die mounted to the lead frame via a plurality of bumps that are shaped or tapered. Each of the plurality of bumps includes a first end connected to the semiconductor die and an opposing, second end connected to the lead frame. The first end has an end surface area A1. The second end has an end surface area A2. The end surface area A1 of the first end is less than the end surface area A2 of the second end. Other aspects are disclosed.

A release layer is formed on a surface of an integrated circuit wafer. The surface is passivated and includes metal contact materials. A stress-engineered film having an intrinsic stress profile is deposited over the release layer. The stress-engineered film is patterned and the release layer is undercut etched so that a released portion of the patterned stress-engineered film is released from the surface while leaving an anchor portion fixed to the surface. The intrinsic stress profile in the stress-engineered film biases the released portion away from the surface. The released portion is placed entirely within an area defined by the metal contact material.

An integrated circuit (IC) includes a substrate including circuitry configured for a function, the circuitry including at least one stress sensitive circuit portion, with at least a portion of nodes in the circuitry electrically coupled to bond pads provided by a top metal layer. A metal wall that is ring-shaped is positioned above the top metal layer that is not electrically coupled to the circuitry. The stress sensitive circuit portion is with at least a majority of its area within an inner area of the substrate that is framed by the metal wall to provide a cavity.

A semiconductor device including an integrated circuit, a dielectric layer, a plurality of connecting terminals and at least one dummy conductor is provided. The integrated circuit has a plurality of connecting pads, and the dielectric layer is disposed thereon and partially exposes the plurality of the connecting pads by a plurality of openings defined therein. The plurality of the connecting terminals is disposed on the plurality of the connecting pads exposed by the plurality of the openings. The at least one dummy conductor is disposed on the dielectric layer and electrically isolated from the integrated circuit. A substantial topology variation is between the plurality of the connecting terminals and the at least one dummy conductor. A semiconductor package having the semiconductor device is also provided.

In one instance, a semiconductor package includes a lead frame and a semiconductor die mounted to the lead frame via a plurality of bumps that are shaped or tapered. Each of the plurality of bumps includes a first end connected to the semiconductor die and an opposing, second end connected to the lead frame. The first end has an end surface area A1. The second end has an end surface area A2. The end surface area A1 of the first end is less than the end surface area A2 of the second end. Other aspects are disclosed.