A semiconductor device includes a first plurality of dies encapsulated by an encapsulant, an interposer over the first plurality of dies, an interconnect structure over and electrically connected to the interposer, and a plurality of conductive pads on a surface of the interconnect structure opposite the interposer. The interposer includes a plurality of embedded passive components. Each die of the first plurality of dies is electrically connected to the interposer. The interconnect structure includes a solenoid inductor in a metallization layer of the interconnect structure.

An embodiment method for forming a semiconductor package includes attaching a first die to a first carrier, depositing a first isolation material around the first die, and after depositing the first isolation material, bonding a second die to the first die. Bonding the second die to the first die includes forming a dielectric-to-dielectric bond. The method further includes removing the first carrier and forming fan-out redistribution layers (RDLs) on an opposing side of the first die as the second die. The fan-out RDLs are electrically connected to the first die and the second die.

A semiconductor package structure is provided. The semiconductor package structure includes a substrate, a semiconductor die, a molding material, a first bonding layer, and a thermal interface material. The semiconductor die is disposed over the substrate. The molding material surrounds the semiconductor die. The first bonding layer is disposed over the semiconductor die. The thermal interface material is disposed over the molding material.

Techniques for interconnecting chips using a bridge chip having through vias is provided. In one aspect, a structure includes: a bridge chip attached to at least a first chip and a second chip, wherein the bridge chip has at least one conductive through via connecting the bridge chip to one of the first chip and the second chip. The bridge chip can include a wiring layer having metal lines present between a first capping layer and a second capping layer, and the at least one conductive through via can directly contact at least a sidewall of at least one of the metal lines. A method of integrating chips using the present bridge chip is also provided.

Integrated circuit assemblies can be fabricated on a wafer scale, wherein a base template, having a plurality of openings, may cover a base substrate, such as a die wafer, wherein the base substrate has a plurality of first integrated circuit devices formed therein and wherein at least one second integrated circuit device is electrically attached to a corresponding first integrated circuit device through a respective opening in the base template. Thus, when the base substrate and base template are singulated into individual integrated circuit assemblies, the individual integrated circuit assemblies will each have a first integrated circuit that is edge aligned to a singulated portion of the base template. The singulated portion of the base template can provide an improved thermal path, mechanical strength, and/or electrical paths for the individual integrated circuit assemblies.

A semiconductor device including a first integrated circuit component, a second integrated circuit component, a third integrated circuit component, and a dielectric encapsulation is provided. The second integrated circuit component is stacked on and electrically coupled to the first integrated circuit component, and the third integrated circuit component is stacked on and electrically coupled to the second integrated circuit component. The dielectric encapsulation is disposed on the second integrated circuit component and laterally encapsulating the third integrated circuit component, where outer sidewalls of the dielectric encapsulation are substantially aligned with sidewalls of the first and second integrated circuit components. A manufacturing method of the above-mentioned semiconductor device is also provided.

A semiconductor package provided herein includes a first semiconductor die, a second semiconductor die and an insulating encapsulation. The second semiconductor die is stacked on the first semiconductor die. The insulating encapsulation laterally surrounds the first semiconductor die and the second semiconductor die in a one-piece form, and has a first sidewall and a second sidewall respectively adjacent to the first semiconductor die and the second semiconductor die. The first sidewall keeps a lateral distance from the second sidewall.

A die stack structure including a first semiconductor die, a second semiconductor die, an insulating encapsulation and a redistribution circuit structure is provided. The first semiconductor die includes a first semiconductor substrate including a first portion and a second portion, a first interconnect structure and a first bonding structure. The first interconnect structure is disposed on a top surface of the second portion, a lateral dimension of the first portion is greater than a lateral dimension of the top surface of the second portion. The second semiconductor die is disposed on the first semiconductor die and includes a second bonding structure, the second semiconductor die is electrically connected with the first semiconductor die through the first and second bonding structures. The insulating encapsulation is disposed on the first portion and laterally encapsulating the second portion and the second semiconductor die. The redistribution circuit structure is electrically connected with the first and second semiconductor dies, and the lateral dimension of the first portion is greater than a lateral dimension of the redistribution circuit structure.

An electronic package is provided, which includes: an electronic element having an active surface with a plurality of electrode pads, an inactive surface opposite to the active surface, and a side surface adjacent to and connecting the active and inactive surfaces; a plurality of conductive elements formed on the electrode pads of the electronic element; and an encapsulant covering the active and side surfaces of the electronic element and portions of side surfaces of the conductive elements and exposing the inactive surface of the electronic element. Therefore, the invention enhances the structural strength of the active surface of the electronic element so as to prevent cracking of the electronic element and hence avoid delamination of the conductive elements from the electronic element.

An electronic device includes a support and a component in the form of an integrated circuit chip having a rear face mounted above a front face of the support and a front face opposite its rear face. A block is provided for at least partially encapsulating the component above the front face of the support. The device also includes at least one thermal dissipation member having a flexible sheet having at least two portions folded onto one another while forming at least one fold between them, these portions facing one another at least partly.