An electronic substrate may be fabricated having a core comprising a laminate including a metal layer between a first insulator layer and a second insulator layer, a metal via through the core, and metallization features on a first side and a second side of the core, wherein first ones of the metallization features are embedded within dielectric material on the first side of the core, and wherein a sidewall of the dielectric material and of the first insulator layer defines a recess over an area of the metal layer. In an embodiment of the present description, an integrated circuit package may be formed with the electronic substrate, wherein at least two integrated circuit devices may be attached to the electronic substrate. In a further embodiment, the integrated circuit package may be electrically attached to an electronic board. Other embodiments are disclosed and claimed.

A semiconductor device includes: a multilayer wiring substrate including a plurality of wiring layers; a first semiconductor chip disposed on the wiring substrate; and a bonding layer bonding the first semiconductor chip to the wiring substrate. A trace formed on the wiring substrate includes a first trace width portion and a second trace width portion, a width of the first trace width portion being greater than the second trace width portion.

A semiconductor device package and a method for manufacturing the semiconductor device package are provided. The semiconductor device package includes a first substrate, a second substrate and an interconnection. The second substrate is arranged above the first substrate and has an opening. The interconnection passes through the opening and connects to the first substrate and the second substrate.

Semiconductor dice are arranged on a substrate such as a leadframe. Each semiconductor die is provided with electrically-conductive protrusions (such as electroplated pillars or bumps) protruding from the semiconductor die opposite the substrate. Laser direct structuring material is molded onto the substrate to cover the semiconductor dice arranged thereon, with the molding operation leaving a distal end of the electrically-conductive protrusion to be optically detectable at the surface of the laser direct structuring material. Laser beam processing the laser direct structuring material is then performed with laser beam energy applied at positions of the surface of the laser direct structuring material which are located by using the electrically-conductive protrusions optically detectable at the surface of the laser direct structuring material as a spatial reference.

A system for forming a conformal electromagnetic interference shield on at least one singulated electronic package (300), including a tray preparation module that prepares a tray (200) by mounting an electromagnetic interference tape (202) onto a frame (201), with the electromagnetic interference tape (202) covering the entirety of the frame (201), a pick and place module for placing at least one singulated electronic packages (300) onto the tray (200), a jig (100) for supporting the tray (200) having the singulated electronic packages (300), and a sputtering machine that forms a conformal electromagnetic interference shield onto the singulated electronic packages (300) through a sputtering process. The jig (100) includes a body having an arcuate surface (101), wherein the arcuate surface (101) of the jig (100) allows substantially continuous contact between the jig (100) and the electronic package (300).

A flip-chip semiconductor package with improved heat dissipation capability and low package profile is provided. The package comprises a heat sink having a plurality of heat dissipation fins and a plurality of heat dissipation leads. The heat dissipation leads are connected to a plurality of thermally conductive vias of a substrate so as to provide thermal conductivity path from the heatsink to the substrate as well as support the heatsink to relieve compressive stress applied to a semiconductor die by the heatsink. The package further comprises an encapsulation layer configured to cover the heat dissipation leads of the heat sink and expose the heat dissipation fins of the heat sink.

Disclosed is a semiconductor package comprising a first redistribution substrate; a solder ball on a bottom surface of the first redistribution substrate; a second redistribution substrate; a semiconductor chip between a top surface of the first redistribution substrate and a bottom surface of the second redistribution substrate; a conductive structure electrically connecting the first redistribution substrate and the second redistribution substrate, the conductive structure laterally spaced apart from the semiconductor chip and including a first conductive structure and a second conductive structure in direct contact with a top surface of the first conductive structure; and a conductive seed pattern between the first redistribution substrate and the first conductive structure. A material of first conductive structure and a material of the second conductive structure may be different from a material of the solder ball.

At least some embodiments of the present disclosure relate to a wearable device. The wearable device comprises a substrate, a detecting module disposed on the substrate, and a control module disposed on the substrate. The control module is electrically connected to the detecting module. The control module is configured to receive a signal from the detecting module and to control the wearable device in response to the signal.

A device and method for providing enhanced bridge structures is disclosed. A set of conducting and insulating layers are deposited and lithographically processed. The conducting layers have uFLS routing. A bridge with uFLS contacts and die disposed on the underlying structure such that the die are connected with the uFLS contacts and uFLS routing. For core-based structures, the layers are formed after the bridge is placed on the underlying structure and the die connected to the bridge through intervening conductive layers. For coreless structures, the layers are formed over the bridge and carrier, which is removed prior to bonding the die to the bridge, and the die bonded directly to the bridge.

Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a package substrate having a first surface and an opposing second surface; and a die embedded in the package substrate, wherein the die has a first surface and an opposing second surface, the die has first conductive contacts at the first surface and second conductive contacts at the second surface, and the first conductive contacts and the second conductive contacts are electrically coupled to conductive pathways in the package substrate.