A semiconductor device package structure is provided. The semiconductor device package structure includes a substrate having a cavity, and phase change material within the cavity. In an example, the phase change material has a phase change temperature lower than 120 degree centigrade. A die may be coupled to the substrate. In an example, the semiconductor device package structure includes one or more interconnect structures that are to couple the die to the phase change material within the cavity.

A semiconductor packaging device includes a wiring board, a working chip, a heat-dissipating metal lid and a silicon thermal conductivity element. The working chip is mounted on the wiring board, and in-built with an working circuit therein. The silicon thermal conductivity element is thermally coupled to the working chip and the heat-dissipating metal lid, and is electrically isolated from the working circuit and the wiring board.

A semiconductor packaging device includes a wiring board, a working chip, a heat-dissipating metal lid and a silicon thermal conductivity element. The working chip is mounted on the wiring board, and in-built with an working circuit therein. The silicon thermal conductivity element is thermally coupled to the working chip and the heat-dissipating metal lid, and is electrically isolated from the working circuit and the wiring board.

Method for packaging a semiconductor die assemblies. In one embodiment, a method is directed to packaging a semiconductor die assembly having a first die and a plurality of second dies arranged in a stack over the first die, wherein the first die has a peripheral region extending laterally outward from the stack of second dies. The method can comprise coupling a thermal transfer structure to the peripheral region of the first die and flowing an underfill material between the second dies. The underfill material is flowed after coupling the thermal transfer structure to the peripheral region of the first die such that the thermal transfer structure limits lateral flow of the underfill material.

Semiconductor device assemblies having stacked semiconductor dies and electrically functional heat transfer structures (HTSs) are disclosed herein. In one embodiment, a semiconductor device assembly includes a first semiconductor die having a mounting surface with a base region and a peripheral region adjacent the base region. At least one second semiconductor die can be electrically coupled to the first semiconductor die at the base region. The device assembly can also include an HTS electrically coupled to the first semiconductor die at the peripheral region.

Apparatuses and methods for providing thermal pathways from a substrate to a thermal bonding pad. The thermal pathways may be metal extensions of the thermal bonding pad that are disposed in channels formed in a backside passivation layer underneath the thermal bonding pad, and may be in direct contact with an underlying substrate. The thermal pathways may provide improved thermal dissipation from the substrate.

Thermal heat spreaders and/or an IC die with solderable thermal structures may be assembled together with a solder array thermal interconnects. A thermal heat spreader may include a non-metallic material and one or more metallized surfaces suitable for bonding to a solder alloy employed as thermal interface material between the heat spreader and an IC die. An IC die may include a metallized back-side surface similarly suitable for bonding to a thermal interconnect comprising a solder alloy. Metallization on the IC die and/or heat spreader may comprise a plurality of solderable structures. A multi-chip package may include multiple IC die having different die thickness that are accommodated by a z-height thickness variation in the thermal interconnects and/or the solderable structures of the IC die or heat spreader.

Thermal heat spreaders and/or an IC die with solderable thermal structures may be assembled together with a solder array thermal interconnects. A thermal heat spreader may include a non-metallic material and one or more metallized surfaces suitable for bonding to a solder alloy employed as thermal interface material between the heat spreader and an IC die. An IC die may include a metallized back-side surface similarly suitable for bonding to a thermal interconnect comprising a solder alloy. Metallization on the IC die and/or heat spreader may comprise a plurality of solderable structures. A multi-chip package may include multiple IC die having different die thickness that are accommodated by a z-height thickness variation in the thermal interconnects and/or the solderable structures of the IC die or heat spreader.

A package comprising a substrate comprising a first surface and a second surface, a passive device coupled to the first surface of the substrate, a first encapsulation layer located over the first surface of the substrate, wherein the first encapsulation layer encapsulates the passive device, an integrated device coupled to the second surface of the substrate, a second encapsulation layer located over the second surface of the substrate, wherein the second encapsulation layer encapsulates the integrated device, a plurality of through encapsulation layer interconnects coupled to the substrate, a plurality of encapsulation layer interconnects coupled to the plurality of through encapsulation layer interconnects, and at least one dummy interconnect located in the second encapsulation layer, wherein the at least one dummy interconnect is located vertically over a back side of the integrated device.

An RF circuit module includes a module substrate, a first substrate in which a first circuit is implemented, and a second substrate in which a second circuit is implemented. The first circuit includes a control circuit that controls an operation of the second circuit. The second circuit includes a radio-frequency amplifier circuit that amplifies an RF signal. The second substrate is mounted on the first substrate. The first substrate is disposed on the module substrate such that a circuit forming surface faces the module substrate. The first substrate and the second substrate have a circuit-to-circuit connection wire that electrically connects the first circuit and the second circuit without intervening the module substrate.