A circuit board is formed from a catalytic laminate having a resin rich surface with catalytic particles dispersed below a surface exclusion depth. Trace channels and apertures are formed into the catalytic laminate, electroless plated with a metal such as copper, filled with a conductive paste containing metallic particles, which are then melted to form traces. In a variation, multiple circuit board layers have channels formed into the surface below the exclusion depth, apertures formed, are electroless plated, and the channels and apertures filled with metal particles. Several such catalytic laminate layers are placed together and pressed together under elevated temperature until the catalytic laminate layers laminate together and metal particles form into traces for a multi-layer circuit board.

A method for forming a laminated structure of a touch panel, the method comprising: after forming a metal line and a bridge line, adding a metallization additive, and metallizing plating the metal line and the bridge line. The present invention is applied to a transparent conductive layer with bridge lines, metal lines, and T-bar. The metal line and the bridge line are fabricated in the same layer, which can reduce the processes and reduce the material cost, and the metallization plating after forming can reduce the stretching effects of the conductive material.

A multi-layer circuit board is formed by positioning a top sub having traces on at least one side to one or more pairs of composite layers, each composite layer comprising an interposer layer and a sub layer. Each sub layer which is adjacent to an interposer layer having an interconnection aperture, the interconnection aperture positioned adjacent to interconnections having a plated through via or pad on each corresponding sub layer. Each interposer aperture is filled with a conductive paste, and the stack of top sub and one or more pairs of composite layers are placed into a lamination press, the enclosure evacuated, and an elevated temperature and laminated pressure is applied until the conductive paste has melted, connecting the adjacent interconnections, and the boards are laminated together into completed laminated multi-layer circuit board.

A component carrier including an electrically insulating core, at least one electronic component embedded in the core, and a coupling structure with at least one electrically conductive through-connection extending at least partially therethrough and having a component contacting end and a wiring contacting end. The electronic component directly contacts the component contacting end. The wiring contacting end is directly electrically contacted to the wiring structure. The exterior surface portion of the coupling structure has homogeneous ablation properties and surface recesses filled with an electrically conductive wiring structure. A method includes embedding an electronic component in an electrically insulating core, providing a coupling structure with a conductive connection having a component end and a wiring end, connecting the electronic component directly to the component end, providing a surface portion of the coupling structure with homogeneous ablation properties, patterning the surface portion with recesses and filling the recesses with a wiring structure such that the wiring end is contacted directly.

Embodiments describe the selective electroless plating of dielectric layers. According to an embodiment, a dielectric layer is patterned to form one or more patterned surfaces. A seed layer is then selectively formed along the patterned surfaces of the dielectric layer. An electroless plating process is used to deposit metal only on the patterned surfaces of the dielectric layer. According to an embodiment, the dielectric layer is doped with an activator precursor. Laser assisted local activation is performed on the patterned surfaces of the dielectric layer in order to selectively form a seed layer only on the patterned surfaces of the dielectric layer by reducing the activator precursor to an oxidation state of zero. According to an additional embodiment, a seed layer is selectively formed on the patterned surfaces of the dielectric layer with a colloidal or ionic seeding solution.

A wiring substrate includes a substrate containing a resin as a main component and including a mixed layer in which the resin and a catalyst are mixed together; and a metal wire disposed to cover the mixed layer and being in contact with the catalyst. The wiring substrate with such a configuration can increase the adhesion of the metal wire to the substrate.

A method for manufacturing electrically conductive structures, preferably conductive pathway structures using laser beams on a non-conductive carrier (LDS method), wherein a non-conductive carrier material is provided which contains at least one inorganic metal phosphate compound and at least one stabiliser finely distributed or dissolved therein, the carrier material is irradiated in regions by laser beams generating the electrically conductive structures in the irradiated regions.

A circuit board is formed from a non-catalytic laminate coated with an optically curable catalytic adhesive, which, after curing with an optical source such as UV, has a resin rich surface with catalytic particles dispersed below a surface exclusion depth. The catalytic laminate is subjected to a drilling and blanket surface plasma etch operation to expose the catalytic particles, followed by an electroless plating operation which deposits a thin layer of conductive material on the surface. A photo-masking step follows to define circuit traces, after which an electro-plating deposition occurs, followed by a resist strip operation and a quick etch to remove electroless copper which was previously covered by photoresist.

A component carrier for carrying electronic components includes an at least partially electrically insulating core, at least one electronic component embedded in the core, and a coupling structure with at least one electrically conductive through-connection extending at least partially therethrough and having a component contacting end and a wiring contacting end. The at least one electronic component is electrically contacted directly to the component contacting end. At least an exterior surface portion of the coupling structure has homogeneous ablation properties and is patterned so as to have surface recesses filled with an electrically conductive wiring structure, and the wiring contacting end is electrically contacted directly to the wiring structure.

A multi-layer circuit board is formed by positioning a top sub having traces on at least one side to one or more pairs of composite layers, each composite layer comprising an interposer layer and a sub layer. Each sub layer which is adjacent to an interposer layer having an interconnection aperture, the interconnection aperture positioned adjacent to interconnections having a plated through via or pad on each corresponding sub layer. Each interposer aperture is filled with a conductive paste, and the stack of top sub and one or more pairs of composite layers are placed into a lamination press, the enclosure evacuated, and an elevated temperature and laminated pressure is applied until the conductive paste has melted, connecting the adjacent interconnections, and the boards are laminated together into completed laminated multi-layer circuit board.