Devices produced by patterning electroless metals on a substrate are presented. An active catalyst layer on the substrate is covered with a patterned mask and treated with a deactivating chemical reagent, which deactivates the catalyst layer not covered by the mask. Once the patterned mask is removed, the electroless metal layer can be placed to have a patterned electroless metals. Alternatively, a substrate can be coated with a blocking reagent in a pattern first to inhibit formation of the catalyst layer before a catalyst layer can be placed over the blocking agent layer and then electroless metal layer is placed on the catalyst layer. The pattern of the blocking reagent acts as a negative pattern of the final conductive line pattern.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

A photosensitive resin composition includes a binder polymer, a photopolymerizable compound, and a photopolymerization initiator. The binder polymer has a structural unit derived from a (meth)acrylic acid, a structural unit derived from styrene or -methylstyrene, and a structural unit derived from a hydroxyalkyl (meth)acrylate ester having a hydroxyalkyl group having from 1 to 12 carbon atoms. The photopolymerizable compound include a bisphenolic di(meth)acrylate having from 1 to 20 structural units of an ethyleneoxy group and having from 0 to 7 structural units of a propyleneoxy group.

A method of forming a metal pattern includes forming a catalyst adsorption layer by bringing a surface of a substrate into contact with a solution, the substrate having a base region and a plurality of protrusions provided on the base region, the base region includes a first material, the protrusions includes a second material different from the first material, the first and the second material being exposed on the surface, and the solution containing a compound having a triazine skeleton, a first functional group of any one of a silanol group and an alkoxysilyl group, and a second functional group of at least one selected from the group consisting of an amino group, a thiol group, and an azido group, forming a catalyst layer on the catalyst adsorption layer, forming a metal film on the catalyst layer by an electroless plating method, and removing the metal film on the protrusions.

A printed wiring board includes a laminate including resin insulating layers and conductor layers such that the resin insulating layers and the conductor layers are laminated alternately and that the laminate has a through hole opening to a first surface of the laminate and a component accommodating cavity that accommodates an electronic component and having an opening part formed on a second surface of the laminate on the opposite side with respect to the first surface. The through hole is formed through the laminate such that the through hole is extending to the component accommodating cavity, and the laminate has a resin coating formed on an inner wall surface of the through hole.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

The present invention relates to an electroless plating method, in which electroless plating is performed by contacting a substrate which is patterned with an anti-electroless plating coating with an electroless plating solution, whereby metal is deposited by electroless plating onto portions of the substrate that are not patterned with the anti-electroless plating coating, the anti-electroless plating coating having multiple layers, each of which is obtainable by plasma deposition of a precursor mixture comprising (a) one or more organosilicon compounds, (b) optionally O.sub.2, N.sub.2O, NO.sub.2, H.sub.2, NH.sub.3, N.sub.2, SiF.sup.4 and/or hexafluoropropylene (HFP), and (c) optionally He, Ar and/or Kr.

An integrated circuit package and manufacturing method thereof are described. The integrated circuit package includes pin up conductive plating to form an interconnect, where an opening on a patterned fifth layer photo-resist material located at bottom portion of a base developed for etching selectively the base to form at least an internal opening and at least a positioning opening, wherein the internal opening corresponds with an inside area of a first patterned conductive layer, and the positioning opening corresponds with an outside area of the first patterned conductive layer.

An integrated circuit substrate, and method of production, includes an internal patterned mask layer defined by multiple mask units that are spaced apart by gaps on a partially or completely removable carrier, and an internal conductive trace layer formed by one or more internal conductive traces that are deposited into the gaps of each internal patterned mask layer such that each gap is occupied with an internal conductive trace. The internal patterned mask layer is made of a photoimageable dielectric material that is retained in the integrated circuit substrate. Other embodiments include the formation of permanent or removable external patterned mask layer and external conductive trace layer on the topmost and optionally the bottommost internal patterned mask layer and internal conductive trace layer. The substrate can also include an insulating layer to partially or completely encapsulate the external conductive trace layer upon removal of the external patterned mask layer.

Methods and devices for patterning electroless metals on a substrate are presented. An active catalyst layer on the substrate can be covered with a patterned mask and treated with a deactivating chemical reagent, which deactivates the catalyst layer not covered by the mask. Once the patterned mask is removed, the electroless metal layer can be placed to have a patterned electroless metals. Alternatively, a substrate can be coated with a blocking reagent in a pattern first to inhibit formation of the catalyst layer before a catalyst layer can be placed over the blocking agent layer and then electroless metal layer is placed on the catalyst layer. The pattern of the blocking reagent acts as a negative pattern of the final conductive line pattern.