A semiconductor device according to one embodiment, includes: a wiring substrate having a core insulating layer; a semiconductor chip mounted on an upper surface of the wiring substrate; a plurality of solder balls formed on a lower surface of the wiring substrate; and a heat sink having a first portion fixed to a back surface of the semiconductor chip via a first adhesive layer, and a second portion located around the first portion and fixed to the wiring substrate via a second adhesive layer. Here, a portion of the plurality of solder balls is arranged at a position overlapping with each of the second portion of the heat sink and the second adhesive layer. Also, a second thickness of the second adhesive layer is greater than two times a first thickness of the first adhesive layer.

A package structure includes a semiconductor device and an adhesive pattern. The adhesive pattern surrounds the semiconductor device, wherein an angle ? is formed between a sidewall of the semiconductor device and a sidewall of the adhesive pattern, 0?<?<90? wherein the adhesive layer has a first opening misaligned with a corner of the semiconductor device closest to the first opening.

An encapsulation hood is fastened onto electrically conductive zones of a support substrate using springs. Each spring has a region in contact with an electrically conductive path contained in the encapsulation hood and another region in contact with a corresponding one of the electrically conductive zones. The fastening of the part of the encapsulation hood onto the support substrate compresses the springs and further utilizes a bead of insulating glue located between the compressed springs.

A semiconductor package includes a module substrate having opposite top and bottom surfaces, a semiconductor chip provided with bumps and mounted on the top surface of the module substrate via the bumps, and a metal member having a top portion disposed at a level higher than the semiconductor chip with reference to the top surface of the module substrate and including the semiconductor chip in plan view and a side portion extending from the top portion toward the module substrate. The module substrate includes a first metal film disposed on or in at least one of the bottom surface and an internal layer of the module substrate. The first metal film is electrically connected to the bumps and reaches a side surface of the module substrate. The side portion is thermally coupled to the first metal film at the side surface of the module substrate.

A bonding method and a bonding structure are provided. A device substrate is provided including a plurality of semiconductor devices, wherein each of the semiconductor devices includes a first bonding layer. A cap substrate is provided including a plurality of cap structures, wherein each of the cap structures includes a second bonding layer, the second bonding layer having a planar surface and a first protrusion protruding from the planar surface. The device substrate is bonded to the cap substrate by engaging the first protrusion of the second bonding layer of each of the cap structures with the corresponding first bonding layer of each of the semiconductor devices in the device substrate.

An IC package including an IC and a TIM assembly located on the IC. The TIM assembly includes a lid defining a compartment, a mixed-phase material located in the compartment, the mixed-phase material including nanostructures, and a liquid metal occupying open spaces in the compartment that are not occupied by the nanostructures. A method of manufacturing an IC package, including providing the IC and placing the TIM assembly on the IC. A computer having one or more circuits that include the IC package.

A method and structure for packaging a semiconductor device are provided. In an embodiment a first substrate is bonded to a second substrate, which is bonded to a third substrate. A thermal interface material is placed on the second substrate prior to application of an underfill material. A ring can be placed on the thermal interface material, and an underfill material is dispensed between the second substrate and the third substrate. By placing the thermal interface material and ring prior to the underfill material, the underfill material cannot interfere with the interface between the thermal interface material and the second substrate, and the thermal interface material and ring can act as a physical barrier to the underfill material, thereby preventing overflow.

Disclosed herein is a device having a shaped seal ring comprising a workpiece, the workpiece comprising at least one dielectric layer disposed on a first side of a substrate, a seal ring disposed in the at least one dielectric layer, and at least one groove in the seal ring. A lid is disposed over the workpiece, the workpiece extending into a recess in the lid and a first thermal interface material (TIM) contacts the seal ring and the lid, with the first TIM extending into the at least one groove. The workpiece is mounted to the package carrier. A die is mounted over a first side of workpiece and disposed in the recess. A first underfill a disposed under the die and a second underfill is disposed between the workpiece and the package carrier. The first TIM is disposed between the first underfill and the second underfill.

Disclosed herein is a device having a shaped seal ring comprising a workpiece, the workpiece comprising at least one dielectric layer disposed on a first side of a substrate, a seal ring disposed in the at least one dielectric layer, and at least one groove in the seal ring. A lid is disposed over the workpiece, the workpiece extending into a recess in the lid and a first thermal interface material (TIM) contacts the seal ring and the lid, with the first TIM extending into the at least one groove. The workpiece is mounted to the package carrier. A die is mounted over a first side of workpiece and disposed in the recess. A first underfill a disposed under the die and a second underfill is disposed between the workpiece and the package carrier. The first TIM is disposed between the first underfill and the second underfill.

An electronic component mounting substrate includes an insulating base having a rectangular shape in plan view and including a first main surface, a second main surface facing the first main surface, and a recess open on the first main surface, a band-shaped metal layer on a sidewall of the recess, and an electrode extending from a bottom surface of the recess into the insulating base. The electrode has an end disposed in the insulating base, and the end includes an inclined portion inclined toward the second main surface.