An embodiment of an electronic system may be provided so as to have superior coupling by implementing a communication mechanism that provides at least for horizontal communication for example, on the basis of wired and/or wireless communication channels, in the system. Hence, by enhancing vertical and horizontal communication capabilities in the electronic system, a reduced overall size may be achieved, while nevertheless reducing complexity in PCBs coupled to the electronic system. In this manner, overall manufacturing costs and reliability of complex electronic systems may be enhanced.

An electronic component includes a base, a laminate of a plurality of conductive metal material layers, and a solder layer made of AuSn alloy solder. The laminate is disposed on the base. The solder layer is disposed on the laminate. The laminate includes a surface layer made of Au as the conductive metal material layer constituting an outermost layer. The surface layer includes a solder layer-disposing region in which the solder layer is disposed and a solder layer-empty region in which the solder layer is not disposed. The solder layer-disposing region and the solder layer-empty region are spatially separated from each other.

In an embodiment, a chip protection envelope includes a first dielectric layer including at least one organic component having a decomposition temperature of at least 180 C., a semiconductor die embedded in the first dielectric layer, the semiconductor die having a first surface and a thickness t.sub.1. A second dielectric layer is arranged on a first surface of the first dielectric layer, the second dielectric layer including a photodefinable polymer composition, and a conductive layer is arranged on the first surface of the semiconductor die and is electrically coupled to the semiconductor die. The conductive layer has a thickness t.sub.2, wherein t.sub.2t.sub.1/3.

A method includes forming a solder layer on a surface of one or more chips. A lid is positioned over the solder layer on each of the one or more chips. Heat and pressure are applied to melt the solder layer and attach each lid to a corresponding solder layer. The solder layer has a thermal conductivity of 50 W/mK.

A manufacturing method of a semiconductor package includes the following steps. An integrated circuit structure is provided, wherein the integrated circuit structure includes an integrated circuit and a metallization layer covering a back surface of the integrated circuit. An encapsulation material is provided to laterally encapsulate the integrated circuit structure. A redistribution structure is provided over the integrated circuit structure and the encapsulation material, wherein the redistribution structure includes a thermal metal layer furthermost from the integrated circuit structure, wherein the thermal metal layer is thermally coupled to the metallization layer. A solder layer is provided over the thermal metal layer, wherein the solder layer is thermally coupled to the thermal metal layer.

A chip package structure is provided. The chip package structure includes a wiring substrate. The chip package structure includes a chip package over the wiring substrate. The chip package structure includes a first heat conductive structure over the chip package. The chip package structure includes a ring dam over the chip package and surrounding the first heat conductive structure. The ring dam has a gap. The chip package structure includes a heat dissipation lid over the first heat conductive structure and the ring dam.

A semiconductor package includes a substrate, a redistribution circuit layer, and a protective layer. The redistribution circuit layer is over the substrate and includes a plurality of functional pads electrically connected to the substrate, and a dummy pad pattern electrically disconnected from the plurality of functional pads, wherein the dummy pad pattern includes a plurality of pad portions connected to one another. The protective layer is disposed over the redistribution circuit layer and comprising a plurality of first openings spaced apart from one another and respectively revealing the plurality of pad portions.

A semiconductor package includes a first integrated circuit structure, a first encapsulation material laterally encapsulating the first integrated circuit structure, a first redistribution structure, a solder layer, a second integrated circuit structure, a second encapsulation material second laterally encapsulating the second integrated circuit structure and a second redistribution structure. The first integrated circuit structure includes a first metallization layer. The first redistribution structure is disposed over the first integrated circuit structure and first encapsulation material. The first metallization layer faces away from the first redistribution structure and thermally coupled to the first redistribution structure. The solder layer is dispose over the first redistribution structure. The second integrated circuit structure is disposed on the first redistribution structure and includes a second metallization layer in contact with the solder layer. The second redistribution structure is disposed over the second integrated circuit structure and the second encapsulation material.

A semiconductor package includes a substrate, a redistribution circuit layer, and a protective layer. The redistribution circuit layer is over the substrate and includes a plurality of functional pads electrically connected to the substrate, and a dummy pad pattern electrically disconnected from the plurality of functional pads, wherein the dummy pad pattern includes a plurality of pad portions connected to one another. The protective layer is disposed over the redistribution circuit layer and comprising a plurality of first openings spaced apart from one another and respectively revealing the plurality of pad portions.

Ultra-thin, hyper-density semiconductor packages and techniques of forming such packages are described. An exemplary semiconductor package is formed with one or more of: (i) metal pillars having an ultra-fine pitch (e.g., a pitch that is greater than or equal to 150 m, etc.); (ii) a large die-to-package ratio (e.g., a ratio that is equal to or greater than 0.85, etc.); and (iii) a thin pitch translation interposer. Another exemplary semiconductor package is formed using coreless substrate technology, die back metallization, and low temperature solder technology for ball grid array (BGA) metallurgy. Other embodiments are described.