The purpose of the present invention is to provide a filling plating system and a filling plating method capable of filling plating sufficiently even if the plating is interrupted between electrolytic plating cells. A filling plating system for forming filling plating in a via hole and/or a through hole of a work to be plated, comprising: a plurality of electrolytic plating cells; and an additive adhesion region arranged between each of the plurality of electrolytic plating cells, wherein solution containing one or more kinds of additive selected from at least a leveler comprising nitrogen-containing organic compound, a brightener comprising sulfur-containing organic compound, and a carrier comprising polyether compound, is directly adhered to the work to be plated at the additive adhesion region.

A cathode is provided for electrolysis of water wherein the cathode material comprises a multi-principal element, transition metal dichalcogenide material that has four or more chemical elements and that is a single phase, solid solution. The pristine cathode material does not contain platinum as a principal (major) component. However, a cathode comprising a transition metal dichalcogenide having platinum (Pt) nanosized islands or precipitates disposed thereon is also provided.

A cathode is provided for electrolysis of water wherein the cathode material comprises a multi-principal element, transition metal dichalcogenide material that has four or more chemical elements and that is a single phase, solid solution. The pristine cathode material does not contain platinum as a principal (major) component. However, a cathode comprising a transition metal dichalcogenide having platinum (Pt) nanosized islands or precipitates disposed thereon is also provided.

A method for manufacturing a printed wiring board includes forming a seed layer on a surface of a resin insulating layer, applying liquid resist on the seed layer formed on the surface of the resin insulating layer, drying the liquid resist applied on the seed layer such that a resist layer is formed on the seed layer, applying pressure and heat simultaneously to an entire surface of the resist layer formed on the seed layer, forming a plating resist on the seed layer from the resist layer formed on the seed layer using a photographic technology, forming an electrolytic plating film on part of the seed layer exposed from the plating resist, removing the plating resist from the seed layer, and removing part of the seed layer exposed from the electrolytic plating film.

A method for processing a smooth or structured surface of a pressing element is described, the method comprising the steps of: a) chrome-plating said surface of the pressing element so as to form a coating comprising a first layer having chrome grains oriented in a first direction and a second layer overlapping said first layer, said second layer having chrome grains oriented in a second direction which is different from said first direction; b) applying a mask on the chrome-plated surface of the pressing element by means of a digital printing technology; c) chemically treating the chrome-plated surface of the pressing element on which said mask was applied, said chemical treatment being performed so as to partially remove said chrome coating in the exposed areas of said chrome-plated surface, i.e. in the areas not being protected by said mask, and d) removing said mask from the chrome-plated surface of the pressing element, obtaining a smooth or structured surface having a coating with areas having a different grade of gloss and colour.

A pressing element obtained by the above processing method and a method for the production of coated panels, such as panels for furniture or floors, bearing a predetermined decorative pattern which uses such pressing element are also described.

An electrodeposition composition comprising: (a) a source of copper ions; (b) an acid; (c) a suppressor; and (d) a leveler, wherein the leveler comprises a quaternized dipyridyl compound prepared by reacting a dipyridyl compound with a difunctional alkylating agent or a quaternized poly(epihalohydrin). The electrodeposition composition can be used in a process for forming a copper feature over a semiconductor substrate in wafer level packaging to electrodeposit a copper bump or pillar on an underbump structure of a semiconductor assembly.

A method for manufacturing a wiring board capable of improving adhesion between an underlayer and a seed layer. An electrically conductive underlayer is disposed on the surface of an insulating substrate and a seed layer containing metal is disposed on the surface of the underlayer to prepare a substrate with seed-layer. A diffusion layer in which elements forming the underlayer and seed layer are mutually diffused is formed between the underlayer and the seed layer, by irradiating the seed layer with a laser beam. A metal layer is formed on the surface of the seed layer by disposing a solid electrolyte membrane between an anode and the seed layer as a cathode and applying voltage between the anode and the underlayer. An exposed portion without the seed layer of the underlayer is removed from the insulating substrate.

In a plating method for mounting a tubular workpiece having openings at both ends in an axial direction thereof on a power feeding clip and immersing the tubular workpiece in a circulated plating solution to plate the tubular workpiece, the mounting of the tubular workpiece on the power feeding clip is performed by inserting the power feeding clip into the tubular workpiece from one of the openings of the tubular workpiece. The power feeding clip is configured by a folded metal plate, and includes a plurality of elastic contact pieces that can elastically contact the inner surface of the tubular workpiece to hold the tubular workpiece and supply power to the tubular workpiece, and a restraining part that is located inside the tubular workpiece and restrains flow of the plating solution in the axial direction.

In a plating method for mounting a tubular workpiece having openings at both ends in an axial direction thereof on a power feeding clip and immersing the tubular workpiece in a circulated plating solution to plate the tubular workpiece, the mounting of the tubular workpiece on the power feeding clip is performed by inserting the power feeding clip into the tubular workpiece from one of the openings of the tubular workpiece. The power feeding clip is configured by a folded metal plate, and includes a plurality of elastic contact pieces that can elastically contact the inner surface of the tubular workpiece to hold the tubular workpiece and supply power to the tubular workpiece, and a restraining part that is located inside the tubular workpiece and restrains flow of the plating solution in the axial direction.

Nanotwinned copper and non-nanotwinned copper may be electroplated to form mixed crystal structures such as 2-in-1 copper via and RDL structures or 2-in-1 copper via and pillar structures. Nanotwinned copper may be electroplated on a non-nanotwinned copper layer by pretreating a surface of the non-nanotwinned copper layer with an oxidizing agent or other chemical reagent. Alternatively, nanotwinned copper may be electroplated to partially fill a recess in a dielectric layer, and non-nanotwinned copper may be electroplated over the nanotwinned copper to fill the recess. Copper overburden may be subsequently removed.