Methods, systems and produced printed substrates are provided, which include substrates composed of one or more materials which are treated by an intermediate layer for normalizing surface energies and a digitally printed formulation adapted to the normalized surface energies. Surface energy normalization may be carried out by physical processes or by selective chemical processes. In an example, a self-assembled monolayer is applied to the surface of a printed circuit board to control ink jet dots by reducing copper surface energy and to improve ink adhesion. The self-assembled monolayer binds via an α group selectively and covalently to the copper on the board and binds via a hydrophobic ω group to solder mask ink that is applied to the board. The ω group participates in the solidification process of the ink.

There is a problem that contact resistance increases due to formation of an oxide film on a contact interface or biting of abrasion powder caused by micro-sliding when a contact connecting portion of a connection terminal including non-noble metal members is exposed to high temperature environment or a repetitious temperature cycle. An object of the present invention is to provide an in-vehicle electronic module that has connection reliability equivalent to that of the conventional in-vehicle electronic module even when being placed in the environment of an engine compartment and can achieve cost reduction by reducing the number of parts and assembly steps. The electronic module includes a mounting board having a circuit board on which an electronic component is mounted, and a case member for accommodating and protecting the mounting board from surrounding environment, The electronic module has a connection structure in which a portion of the circuit board is protruded to the outside through an opening of the case and inserts a board terminal into an external female connector to obtain electrical continuity, and a portion of the case member forms a connector housing that receives the female connector and isolates a space in which the board terminal is present from surrounding environment and an insulating resin member for fixing the circuit board in the case is integrally molded or joined with the circuit board.

A resin composition, a copper-clad laminate using the same, and a printed circuit board using the same are introduced. The resin composition comprises a specific phosphorus-containing salt and a prepolymer of vinyl-containing polyphenylene ether. The resin composition features specific ingredients and proportion to thereby achieve satisfactory properties of prepreg made from the resin composition, and attain satisfactory laminate properties, such as high degree of heat resistance and satisfactory dielectric properties, and thus is suitable for producing a prepreg or a resin film to thereby be applicable to copper-clad laminates and printed circuit boards.

A method for selective processing of a panel, the method may include receiving a panel that has a bottom side and a top side and comprises a first group of drilled holes and a second group of drilled holes; at least partially sealing a bottom of any through hole of the first group; filling, by a selective filing process, any drilled hole of the first group that has a top opening to provide at least partially filled drilled holes of the first group without filling the second group of drilled holes; and plugging, by a selective plugging process, a top of any drilled hole of the first group.

A method of manufacturing a support body includes: (a) preparing a support substrate; (b) preparing a metal foil on which a peeling layer is provided; (c) providing an adhesion adjusting layer on the support substrate in a certain region of the support substrate excluding an outer peripheral portion of the support substrate, wherein the adhesion adjusting layer is configured to adjust a contact area between the peeling layer and the support substrate; and (d) providing the metal foil on the support substrate such that the peeling layer provided on the metal foil faces the support substrate via the adhesion adjusting layer. In step (d), the adhesion adjusting layer is adhered to the support substrate, and the peeling layer is adhered to the outer peripheral portion of the support substrate, and is in contact with the adhesion adjusting layer but is not adhered to the adhesion adjusting layer.

A printed circuit board includes a first insulating layer; a first circuit pattern embedded in the first insulating layer; a second insulating layer disposed on the first insulating layer; a via hole penetrating at least a portion of each of the first and second insulating layers; and an adhesive layer disposed on at least a portion of a side surface of the via hole.

Techniques and mechanisms for bonding structures of a circuit device with a monolayer. In an embodiment, a patterned metallization layer or a first dielectric layer includes a first surface portion. The first surface portion is exposed to first molecules which each include a first head group and a first end group which is substantially non-reactive with the first head group. The first head groups attach to the first portion to form a first self-assembled monolayer, which is subsequently reacted with second molecules to form a second monolayer comprising moieties of the first molecules. In another embodiment, the first head group comprises a first moiety comprising a sulfur atom or a nitrogen atom, where the first end group comprises one of an acid moiety, an acid anhydride moiety, an aliphatic alcohol moiety, an aromatic alcohol moiety, or an unsaturated hydrocarbon moiety.

The present invention relates to a printing method comprising a step of printing a pattern on a substrate, preferably by ink jet printing, followed by a gold plating step by means of contact between the pre-printed pattern to be gold plated and a gold plating deposition device, such as a preferably conductive metal sheet, e.g. a multilayer film comprising a preferably conductive metal sheet.

A high thermal conductivity prepreg is provided. The high thermal conductivity prepreg includes a high thermal conductivity reinforcing material and a dielectric material layer formed on the surface of the high thermal conductivity reinforcing material, wherein the high thermal conductivity reinforcing material is prepared by a process which includes the following steps: (a) providing a precursor aqueous solution, the precursor aqueous solution includes a precursor selected from the group of organic salts, inorganic salts, and combinations thereof; (b) subjecting the precursor aqueous solution to a hydrolysis reaction to form an intermediate product aqueous solution; (c) subjecting the intermediate product aqueous solution to a condensation polymerization reaction to form a pretreatment solution; (d) impregnating a reinforcing material with the pretreatment solution; and (e) oven-drying the impregnated reinforcing material to obtain the high thermal conductivity reinforcing material.

An interconnect substrate includes a first insulating layer, an interconnect layer formed on a first surface of the first insulating layer, and a second insulating layer formed on the first surface of the first insulating layer to cover the interconnect layer, wherein the second insulating layer includes a first resin layer and a second resin layer, the first resin layer covering at least part of a surface of the interconnect layer exposed outside the first insulating layer, the second resin layer covering the first resin layer, wherein both the first resin layer and the second resin layer contain a resin and a filler, and wherein a proportion of the resin in the first resin layer per unit area is higher than a proportion of the resin in the second resin layer per unit area.