Disclosed herein are lids for integrated circuit (IC) packages with solder thermal interface materials (STIMs), as well as related methods and devices. For example, in some embodiments, an IC package may include a STIM between a die of the IC package and a lid of the IC package. The lid of the IC package may include nickel, the IC package may include an intermetallic compound (IMC) between the STIM and the nickel, and the lid may include an intermediate material between the nickel and the IMC.

A semiconductor device structure is provided. The semiconductor device structure includes a first conductive line over a substrate. The semiconductor device structure includes a first protection cap over the first conductive line. The semiconductor device structure includes a first photosensitive dielectric layer over the substrate, the first conductive line, and the first protection cap. The semiconductor device structure includes a conductive via structure passing through the first photosensitive dielectric layer and connected to the first protection cap. The semiconductor device structure includes a second conductive line over the conductive via structure and the first photosensitive dielectric layer. The semiconductor device structure includes a second protection cap over the second conductive line. The semiconductor device structure includes a second photosensitive dielectric layer over the first photosensitive dielectric layer, the second conductive line, and the second protection cap.

Disclosed is an electromagnetic wave shielding structure. The electromagnetic wave shielding structure comprises: a printed circuit board having a plurality of elements mounted therein and having a ground pad surrounding the plurality of elements; an insulation member made of a pre-molded insulating material and attached to the printed circuit board to surround the plurality of elements; and a conductive coating layer covering an exterior surface of the insulation member, wherein the conductive coating layer is connected to the ground pad.

A device (2) is formed on a main surface of a substrate (1). The main surface of the substrate (1) is bonded to the undersurface of the counter substrate (14) via the bonding member (11,12,13) in a hollow state. A circuit (17) and a bump structure (26) are formed on the top surface of the counter substrate (14). The bump structure (26) is positioned in a region corresponding to at least the bonding member (11,12,13), and has a higher height than that of the circuit (17).

Structures and methods of fabricating semiconductor wafer assemblies that encapsulate one or die in a cavity etched into an oxide bonded semiconductor wafer stack. The methods generally include the steps of positioning the die in the cavity, mechanically and electrically mounting the die to the wafer stack, and encapsulating the die within the cavity by bonding a lid wafer to the wafer stack in one of multiple ways. Semiconductor processing steps are applied to construct the assemblies (e.g., deposition, annealing, chemical and mechanical polishing, etching, etc.) and connecting the die (e.g., bump bonding, wire interconnecting, ultrasonic bonding, oxide bonding, etc.) according to the embodiments described above.

A method for forming a semiconductor device structure is provided. The method includes forming a first conductive line over a substrate. The method includes forming a first protection cap over a first portion of the first conductive line. The first protection cap and the first conductive line are made of different conductive materials. The method includes forming a first photosensitive dielectric layer over the substrate, the first conductive line, and the first protection cap. The method includes forming a first opening in the first photosensitive dielectric layer and over the first protection cap. The method includes forming a conductive via structure and a second conductive line over the first conductive line. The conductive via structure is in the first opening and over the first protection cap, and the second conductive line is over the conductive via structure and the first photosensitive dielectric layer.

Hexagonally arranged connection patterns for device packaging allow high density circuitry dies to be assembled into packages of manufacturable size. The connection patterns may be patterns for solder ball arrays or other types of connection mechanisms under a semiconductor package. Despite the increased density of the connection patterns, the connection patterns meet the demanding crosstalk specifications for high speed operation of the high density circuitry.

An integrated circuit structure may be formed using a phase change material to substantially fill at least one chamber within the integrated circuit assembly to increase thermal capacitance. The integrated circuit assembly may comprise a substrate, at least one integrated circuit device electrically attached to the substrate, a heat dissipation device, a thermal interface material between the integrated circuit device and the heat dissipation device, a chamber defined by the heat dissipation device, the substrate, and the integrated circuit device, and a phase change material within the chamber.

This application provides a chip package structure. The chip package structure includes: a substrate and a chip, and further includes: a heat dissipation ring fastened onto the substrate and a planar heat pipe radiator covering the heat dissipation ring. The substrate, the heat dissipation ring, and the planar heat pipe radiator form a space to enclose the chip. A first metal thin film is disposed on a surface, facing the chip, of the planar heat pipe radiator, and the chip is thermally coupled to the first metal thin film by using a sintered metal layer.

An electronic package includes a carrier and a semiconductor chip. In a first aspect, a lid is attached to the chip and subsequently the gap between the lid and the carrier is filled by a seal band that includes seal band material and a plurality of shim members. In another aspect, an interleaved seal band includes a pattern of a first type of seal band material and a second type of seal band material. In another aspect, the lid includes a plurality of surfaces at different topographies to reduce the thickness of the seal band between the topographic lid and the carrier. In yet another aspect the electronic package further includes a frame concentric with the chip. The lid is attached to the frame with a solder, epoxy or elastomer and placed on the chip with a thermal interface material. The seal band material is dispensed on the chip carrier and the frame is then moved towards the chip carrier allowing a minimum seal band thickness.