A device includes an interposer, which includes a substrate; and at least one dielectric layer over the substrate. A plurality of through-substrate vias (TSVs) penetrate through the substrate. A first metal bump is in the at least one dielectric layer and electrically coupled to the plurality of TSVs. A second metal bump is over the at least one dielectric layer. A die is embedded in the at least one dielectric layer and bonded to the first metal bump.

A modulated inductance module includes an inductor including one or more electrical conductors disposed around a ferromagnetic ceramic element formed on a semiconductor die, wherein the inductor further has two or more metal oxides having fluctuations in metal-oxide compositional uniformity less than or equal to 1.50 mol % throughout said ceramic element, the ceramic element has crystalline grain structure having a diameter that is less than or equal to 1.5 a mean grain diameter, and the semiconductor die contains active semiconductor switches or rectifying components that are in electrical communication with the one or more electrical conductors of the inductor.

Embodiments that allow multi-chip interconnect using organic bridges are described. In some embodiments an organic package substrate has an embedded organic bridge. The organic bridge can have interconnect structures that allow attachment of die to be interconnected by the organic bridge. In some embodiments, the organic bridge comprises a metal routing layer, a metal pad layer and interleaved organic polymer dielectric layers but without a substrate layer. Embodiments having only a few layers may be embedded into the top layer or top few layers of the organic package substrate. Methods of manufacture are also described.

A method for selective metallization includes: selectively adsorbing catalytic nanoparticles onto an imprint mold to form a selectively adsorbed catalytic nanoparticle (SACN) mold; using the SACN mold in an imprinting process to synchronously transfer a pattern and the catalytic nanoparticles onto a film; separating the film from the SACN mold; and selectively depositing metal onto the film based on the pattern transferred to the film.

The present disclosure provides a method for manufacturing a flexible substrate. The method includes forming at least two flexible substrate layers in a stacking form on a surface of a glass baseplate, wherein a first flexible substrate layer of the flexible substrate layers relatively close to the glass baseplate has a refractive index less than a refractive index of a second flexible substrate layer of the flexible substrate layers relatively far from the glass baseplate; forming a water and oxygen blocking layer on a surface of the second flexible substrate layers, wherein the water and oxygen blocking layer has a refractive index greater than the refractive index of the second flexible substrate layers disposed below the water and oxygen blocking layer.

The present disclosure provides a composite conductive substrate exhibiting enhanced properties both in the folding endurance and the electric conductivity and a method of manufacturing the composite conductive substrate. A composite conductive substrate according to an exemplary embodiment of the present disclosure includes: an insulating layer; a metal nanowire structure embedded beneath one surface of the insulating layer; and a metal thin film coupled to the metal nanowire structure. The composite conductive substrate may be fabricated in an order of the insulating film, the metal nanowire structure, and the metal thin film, or vice versa.

A method for manufacturing a flexible circuit board is provided. The method for manufacturing a flexible circuit board includes the following steps: providing a carrier substrate, forming a flexible substrate on the carrier substrate, and forming a plurality of circuit strings on the flexible substrate. A flexible circuit board manufactured by the above method is also provided.

Embodiments that allow multi-chip interconnect using organic bridges are described. In some embodiments an organic package substrate has an embedded organic bridge. The organic bridge can have interconnect structures that allow attachment of die to be interconnected by the organic bridge. In some embodiments, the organic bridge comprises a metal routing layer, a metal pad layer and interleaved organic polymer dielectric layers but without a substrate layer. Embodiments having only a few layers may be embedded into the top layer or top few layers of the organic package substrate. Methods of manufacture are also described.

A manufacturing method for circuit board structure includes steps of providing a carrier, forming a first build-up layer including a plurality of first circuits, forming a second build-up layer including a plurality of second circuits on a side of the first build-up layer located away from the carrier, attaching a side of the second build-up layer located away from the first build-up layer to a core layer, and removing the carrier from the first build-up layer, where the first circuits are finer than the second circuits.

Filing a plated through-hole of a circuit board with solder is facilitated by an apparatus which includes a wire solder assembly and a controller. The wire solder assembly includes a wire probe sized to extend into the plated through-hole from one side of the circuit board, and a solder block associated with the wire probe so that the probe passes through the solder block. The controller controls heating of the wire probe, when the wire probe is operatively inserted into the plated through-hole, by passing a current through the wire probe. The heating of the wire probe heats a conductive plating of the plated through-hole and melts the solder block. The heating of the conductive plating and the melting of the solder block causes the solder to migrate into the plated through-hole by capillary action to fill the plated through-hole with the solder.