A method for manufacturing an integrated multilayer structure includes obtaining a substrate film having first and second sides, providing at least on the first side one or more first functional features, arranging at least one layer upon at least the first side; removing, at least a portion of the substrate film so that space is released in the structure wherein a detachment-enhancing feature provided to the substrate film is configured to facilitate the removal of the at least a portion of the substrate film such that the adjacent remaining film material, if any, the arranged layer and the one or more first functional features are preserved and preferably remain substantially intact; and providing at least one second functional feature into the space released for use so that the at least one second functional feature operatively connects with at least one of the one or more first functional features.

The present invention relates to a method for formation of a redistribution layer using photo-sintering and to the redistribution layer formed by the method. The method for forming a redistribution layer using photo-sintering includes printing, on a substrate, a liquid electrode pattern for a redistribution layer; coating a transparent polymer on the substrate and the pattern; photo-sintering the electrode pattern using photonic energy; and evaporating an organic substance contained in the liquid electrode pattern via the photo-sintering to remove the polymer on a top face of the electrode pattern to form a redistribution layer as the sintered electrode pattern.

Provided are interconnect circuits and methods of forming thereof. A method may involve laminating a substrate to a conductive layer followed by patterning the conductive layer. This patterning operation forms individual conductive portions, which may be also referred to as traces or conductive islands. The substrate supports these portions relative to each other during and after patterning. After patterning, an insulator may be laminated to the exposed surface of the patterned conductive layer. At this point, the conductive layer portions are also supported by the insulator, and the substrate may optionally be removed, e.g., together with undesirable portions of the conductive layer. Alternatively, the substrate may be retained as a component of the circuit and the undesirable portions of the patterned conductive layer may be removed separately. These approaches allow using new patterning techniques as well as new materials for substrates and/or insulators.

A method for manufacturing a device connected body, including: a step A for readying a first laminate having, in the order listed, an inorganic substrate, a resin layer, and a plurality of devices mounted on the resin layer so that a gap is present therebetween; a step B for forming, on the first laminate, an elastomer layer so as to cover the plurality of devices and the gap portion and obtaining a second laminate; and a step C for peeling the inorganic substrate. The resin layer is either formed as a plurality of resin layers in advance at least at positions corresponding to the plurality of devices, or formed as a plurality of resin layers at least at positions corresponding to the plurality of devices by removing a part of the resin layer after step C for peeling the inorganic substrate.

An electronic component module includes a substrate, an electronic component, an insulating resin, and a shield film. The insulating resin covers a first main surface side of the substrate. The insulating resin exposes an opposite surface of the electronic component. The shield film covers the insulating resin and the opposite surface of the electronic component. The opposite surface has an uneven portion. A concave portion of the uneven portion has a smoother shape than a convex portion of the uneven portion.

A multi-layer substrate structure which can be peeled off precisely includes: a substrate; a first flexible dielectric layer formed on the substrate; a peel-off layer formed on the first flexible dielectric layer; and a unit to be peeled off formed on the peel-off layer; wherein an adhesive force between the peel-off layer and the first flexible dielectric layer is smaller than an adhesive force between the first flexible dielectric layer and the substrate, and the substrate, the first flexible dielectric layer, the peel-off layer, and the unit to be peeled off together form the multi-layer substrate structure. A method for manufacturing a multi-layer substrate structure which can be peeled off precisely is also provided.

Provided are interconnect circuits and methods of forming thereof. A method may involve laminating a substrate to a conductive layer followed by patterning the conductive layer. This patterning operation forms individual conductive portions, which may be also referred to as traces or conductive islands. The substrate supports these portions relative to each other during and after patterning. After patterning, an insulator may be laminated to the exposed surface of the patterned conductive layer. At this point, the conductive layer portions are also supported by the insulator, and the substrate may optionally be removed, e.g., together with undesirable portions of the conductive layer. Alternatively, the substrate may be retained as a component of the circuit and the undesirable portions of the patterned conductive layer may be removed separately. These approaches allow using new patterning techniques as well as new materials for substrates and/or insulators.

A semifinished product with a sacrificial structure and two component carriers releasably formed on opposing main surfaces of the sacrificial structure. The sacrificial structure includes a central structure and releasing layers on or over both opposing main surfaces of the central structure The central structure includes a dummy core being covered, in particular fully, on or over both main surfaces thereof with a respective one of two spatially separated sections of separate material, in particular separate dielectric material.

A blade includes an edge to be pressed against an end portion of a carrier film to fold the end portion upwards from a sheet. A clamp mechanism peels the carrier film off from the sheet by moving while clamping the upwardly folded end portion of the carrier film.

A device for removing a portion of cover is provided, which includes a lower platform and an upper platform oppositely disposed, a cover jig between the lower and upper platforms, a feed roller and a receiving roller oppositely disposed, and an adhesive film. The upper platform includes a plurality of protrusions, and each of the protrusions extends toward the lower platform. The cover jig includes a plurality of through holes, and each of the through holes is disposed opposite to each of the protrusions, so that each of the protrusions can be inserted through each of the through holes. One end of the adhesive film is connected to the feed roller, and the other end of the adhesive film is connected to the receiving roller, and a portion of the adhesive film between the two ends is located between the upper platform and the cover jig.