A chip package assembly and method for fabricating the same are provided which utilize a plurality of extra-die heat transfer posts for improved thermal management. In one example, a chip package assembly is provided that includes a first integrated circuit (IC) die mounted to a substrate, a cover disposed over the first IC die, and a plurality of extra-die conductive posts disposed between the cover and substrate. The extra-die conductive posts provide a heat transfer path between the cover and substrate that is laterally outward of the first IC die.

Disclosed is a chip heat dissipating structure, a process and a semiconductor device. The structure includes at least a chip and a package layer, the package layer encapsulates the chip, an intermediate structure for buffering temperature-varying stress generated by an internal structure of the package layer and conducting internal heat is arranged in the package layer. In present disclosure, heat generated by chip silicon is transmitted to each heat conductive protrusion through the intermediate heat conductive layer, then heat dissipation is realized through heat fin. The heat fin cooperates with the bonding pad to form double-sided heat dissipation, with good heat dissipation effect, stress deformation of the heat fin does not directly extrude the chip to avoid damage. Structure of both sides of the chip is relatively symmetrical, which balances a stress effect caused by high and low temperatures. Device has strong reliability, and production cost is low.

A method for mounting an electrical component on a substrate is disclosed. According to the method, joining is simplified using a cover, or hood, that includes a contact structure on an inner side of the hood, wherein when the hood is mounted, the contact structure is joined to the underlying structure at different joining levels simultaneously using an additional material. Moreover, a joining pressure, e.g., for diffusion or sintered bonds for electrical contacts, can be applied using such a hood.

Package structures and methods of forming package structures are discussed. A package structure, in accordance with some embodiments, includes a package component with one or more integrated circuits adhered to a package substrate, a hybrid thermal interface material utilizing a combination of polymer based material with high elongation values and metal based material with high thermal conductivity values. The polymer based thermal interface material placed on the edge of the package component contains the metal based thermal interface material in liquid form.

The present disclosure relates to a hermetic package capable of handling a high coefficient of thermal expansion (CTE) mismatch configuration. The disclosed hermetic package includes a metal base and multiple segments that are discrete from each other. Herein, a gap exists between every two adjacent ceramic wall segments and is sealed with a connecting material. The ceramic wall segments with the connecting material form a ring wall, where the gap between every two adjacent ceramic wall segments is located at a corner of the ring wall. The metal base is either surrounded by the ring wall or underneath the ring wall.

The present disclosure relates to a hermetic package capable of handling a high coefficient of thermal expansion (CTE) mismatch configuration. The disclosed hermetic package includes a metal base and multiple segments that are discrete from each other. Herein, a gap exists between every two adjacent ceramic wall segments and is sealed with a connecting material. The ceramic wall segments with the connecting material form a ring wall, where the gap between every two adjacent ceramic wall segments is located at a corner of the ring wall. The metal base is either surrounded by the ring wall or underneath the ring wall.

A semiconductor package including a semiconductor die and at least one bondline positioned on the semiconductor die, the at least one bondline comprising a nickel lanthanide alloy diffusion barrier layer abutting a gold layer.

A semiconductor device package includes a redistribution layer structure, a semiconductor component, an encapsulant and a sensing component. The semiconductor component is disposed on a top surface of the RDL structure. The encapsulant covers the semiconductor component, the RDL structure, and an electrical connection member. The sensing component is disposed on a top surface of the encapsulant. The electrical connection member is in contact with a pad of the semiconductor component and has a first surface exposed from the top surface of the encapsulant, and the semiconductor component package includes a wire connecting the sensing component and the first surface of the electrical connection member.

The present invention discloses an elastic heat spreader for chip packaging, a packaging structure and a packaging method. The heat spreader includes a top cover plate and a side cover plate that extends outward along an edge of the top cover plate, wherein the top cover plate is configured to be placed on a chip, and at least a partial region of the side cover plate is an elastic member; and the elastic member at least enables the side cover plate to be telescopic in a direction perpendicular to the top cover plate. According to the present invention, a following problem is solved: delamination between the heat spreader and a substrate as well as the chip due to stress generated by different thermal expansion coefficients of the substrate, the heat spreader and the chip in a packaging process of a large-size product.

In one example, an electronic device includes a substrate having a substrate top side, a substrate bottom side opposite to the substrate top side. A first electronic component is connected to the substrate top side and having a first electronic component top side distal to the substrate top side. A second electronic is connected to the substrate top side, laterally spaced apart from the first electronic component, and having a second electronic component top side distal to the substrate top side. A lid is connected to the substrate top side, covering the first electronic component and the second electronic component. The lid includes a lid ceiling; and a lid wall extending from the lid ceiling and defining a lid periphery. A dam structure is connected to the first electronic device top side and the lid ceiling within the lid periphery and having a vent. A first interface material is over the first electronic component top side and contained within the dam structure. A second interface material is over the second electronic component top side and connected to the lid ceiling, where the dam structure separates the first interface material from the second interface material. The first interface material has a higher thermal conductivity than the second interface material. Other examples and related methods are also disclosed herein.