An electroless copper plating bath is an electroless copper plating bath with a pH of 5 to 10 containing a hydrazine compound as a reducing agent and not containing formaldehyde. The electroless copper plating bath comprises at least: an amine-based complexing agent or an amine compound; and an aminocarboxylic acid-based complexing agent.

The present invention relates to a production of electro-conductive traces on the surface of polymeric articles using laser excitation for the areas to be metallised, followed by activation of the laser-treated areas with a metal salt solution, the article is later rinsed in distilled water, and the activated areas are metallised in the chemical plating bath. The aims of the invention are to produce cost-effective conductive traces of the circuits for the application in 3D moulded interconnect devices, to increase the quality of the circuit traces improving the selective metallization process. An irradiation dose and scanning parameters for the surface excitation are chosen experimentally, provided that a negative static charge appears on the surface of the laser-irradiated areas. The chosen parameters ensure that any surface degradation of the polymer is avoided. The activation solution used in the method is aqueous solution consisting of one chosen salt comprising: silver (Ag), copper (Cu), nickel (Ni), cobalt (Co), zinc (Zn), chrome (Cr), tin (Sn) salt.

Upon use of an immersion tin plating solution, contaminants build in the solution, which cause the plating rate and the quality of the plated deposit to decrease. One primary contaminant, which builds in the plating solution upon use, is hydrogen sulfide, H.sub.2S. If a gas is bubbled or blown through the solution, contaminants, especially hydrogen sulfide, can be effectively removed from the solution and, as a result, the high plating rate and plate quality can be restored or maintained. In this regard, any gas can be used, however, it is preferable to use a gas that will not detrimentally interact with the solution, other than to strip out contaminants. Nitrogen is particularly preferred for this purpose because it is efficient at stripping out contaminants, including hydrogen sulfide, but does not induce the oxidation of the tin ions from their divalent state to the tetravalent state, which is detrimental.

A wet type processing apparatus includes a processing bath for reserving inside the processing liquid and rendering the resin film pass through the processing liquid; a pair of conveyance members arranged on a loading side for the resin film of the processing bath and on a delivery side for resin film of the processing bath at a position higher than a liquid surface of the processing liquid reserved in the processing bath; and a spouting unit arranged between the pair of the conveyance members at a position lower than the conveyance members and formed with a circumferential surface having plural holes for spouting the processing liquid from the circumferential surface to change a direction of the resin film along the circumferential surface in a non-contact manner in the processing liquid according to spouted flows from the holes.

A method of performing electroless electrochemical atomic layer deposition is provided and includes: providing a substrate including an exposed upper metal layer; exposing the substrate to a first precursor solution to create a sacrificial metal monolayer on the exposed upper metal layer via underpotential deposition, where the first precursor solution is an aqueous solution including a reducing agent; subsequent to the forming of the sacrificial metal monolayer, rinsing the substrate; subsequent to the rinsing of the substrate, exposing the substrate to a second precursor solution to replace the sacrificial metal monolayer with a first deposition layer; and subsequent to replacing the sacrificial metal monolayer with the first deposition layer, rinsing the substrate. The exposure of the substrate to the first precursor solution and the exposure of the substrate to the second precursor solution are electroless processes.

At least one plating pen is brought into aligned relationship with at least one hole defined in a board. The pen includes a central retractable protrusion, a first shell surrounding the protrusion and defining a first annular channel therewith, and a second shell surrounding the first shell and defining a second annular channel therewith. The protrusion is lowered to block the hole and plating material is flowed down the first channel to a surface of the board and up into the second channel, to form an initial deposit on the board surface. The protrusion is raised to unblock the hole, and plating material is flowed down the first annular channel to side walls of the hole and up into the second annular channel, to deposit the material on the side walls of the hole.

The invention relates to an aqueous plating bath composition and a method for depositing a palladium layer by electroless plating onto a substrate. The aqueous plating bath composition according to the invention comprises a source for palladium ions, a reducing agent for palladium ions and an unsaturated compound. The aqueous plating bath composition according to the invention has an improved stability against undesired decomposition due to the unsaturated compounds while keeping the deposition rate for palladium at the desired satisfying value. The aqueous plating bath composition has also a prolonged life time. The unsaturated compounds of the invention allow for adjusting the deposition rate to a satisfying range over the bath life time and for electrolessly depositing palladium layers at lower temperatures.

The present invention relates to a production of electro-conductive traces on the surface of polymeric articles using laser excitation for the areas to be metallised, followed by activation of the laser-treated areas with a metal salt solution, the article is later rinsed in distilled water, and the activated areas are metallised in the chemical plating bath. The aims of the invention are to produce cost-effective conductive traces of the circuits for the application in 3D moulded interconnect devices, to increase the quality of the circuit traces improving the selective metallization process. An irradiation dose and scanning parameters for the surface excitation are chosen experimentally, provided that a negative static charge appears on the surface of the laser-irradiated areas. The chosen parameters ensure that any surface degradation of the polymer is avoided. The activation solution used in the method is aqueous solution consisting of one chosen salt comprising: silver (Ag), copper (Cu), nickel (Ni), cobalt (Co), zinc (Zn), chrome (Cr), tin (Sn) salt.

The invention relates to an aqueous alkaline cleaner solution for glass filler removal comprising: (a) at least one non-ionic surfactant selected from the group consisting of saturated branched or unbranched C5 to C12 carboxylic acid or salt thereof, wherein the concentration of the (a) at least one surfactant is from 0.9 to 1.7 g/L; (b) at least one surfactant selected from the group consisting of saturated branched or unbranched C5 to C12 alkyl having a negatively charged group selected from sulfate, sulfite, sulfonate, phosphate, phosphite and carbonate, and saturated C3-C8 alkyl amino carboxylate; (c) at least one compound having at least one hydroxyl group and at least one COC group selected from the group consisting of alkoxylated C5-C12 alkanol and glycosidic C5-C12 alkanol; and (d) alkali metal hydroxide, wherein the concentration of the (d) alkali metal hydroxide is from 65 to 200 g/L; and a method for use.

A method of performing electroless electrochemical atomic layer deposition is provided and includes: providing a substrate including an exposed upper metal layer; exposing the substrate to a first precursor solution to create a sacrificial metal monolayer on the exposed upper metal layer via underpotential deposition, where the first precursor solution is an aqueous solution including a reducing agent; subsequent to the forming of the sacrificial metal monolayer, rinsing the substrate; subsequent to the rinsing of the substrate, exposing the substrate to a second precursor solution to replace the sacrificial metal monolayer with a first deposition layer; and subsequent to replacing the sacrificial metal monolayer with the first deposition layer, rinsing the substrate. The exposure of the substrate to the first precursor solution and the exposure of the substrate to the second precursor solution are electroless processes.