A method includes a step of performing a selective catalyst treatment by supplying a catalyst solution to an upper surface of an exposed interconnection layer forming a step portion of a stepped shape formed by pair layers stacked to form the stepped shape, the pair layer including an interconnection layer formed on an insulating layer, and a step of selectively growing a metal layer by performing electroless plating on the upper surface of the interconnection layer on which the catalyst treatment is performed.

The thermally activated building panel (1) includes a metal plate (2) having a room-facing surface (3) and a building-facing surface (4). A heat-exchanger tube (5) for conveying a cooling or heating medium is in conductive thermal contact with the building-facing surface (4) of the metal plate (2). A textile (9) is arranged on the room-facing surface (3) of the metal plate (2) and has a first surface (10) generally contacting the metal plate (2) and a second surface (11) generally visible from said room. The textile (9) is tensioned between opposed edges (12) of the metal plate (2). The first surface (10) of the textile (9) is metallized by deposition of metal particles on the textile (9).

Described herein are methods of applying metals to substrates, where the methods include contacting the substrate with an aqueous metal plating composition comprising polyammonium bisulfate (“PABS”) and a dissolved metal or salt thereof. The methods allow application of metals to the substrate without need for electrical energy input or for an added chemical catalyst, chelating agent, complexing agent, reducing agent, stabilizer, or pH-modifying (or controlling) chemical compound.

It is provided a method for manufacturing a metal coated substrate by forming a metal coating on a surface of a substrate, comprising: immersing the substrate in a palladium/tin colloidal solution; immersing the substrate in an acid solution; and carrying out electroless metal plating in order to obtain a continuous film-coated substrate which is permeable to visible light. It is also provided a metal coated substrate obtainable by the mentioned method and an article of manufacture made of the metal coated substrate.

It is provided a method for manufacturing a metal coated substrate by forming a metal coating on a surface of a substrate, comprising: immersing the substrate in a palladium/tin colloidal solution; immersing the substrate in an acid solution; and carrying out electroless metal plating in order to obtain a continuous film-coated substrate which is permeable to visible light. It is also provided a metal coated substrate obtainable by the mentioned method and an article of manufacture made of the metal coated substrate.

The present invention concerns a tin plating bath comprising tin ions; titanium ions as reducing agent suitable to reduce tin ions to metallic tin; and at least one compound selected from the group consisting sulfites, dithionites, thiosulfates, tetrathionates, polythionates, disulfites, sulfides, disulfide, polysulfide, elemental sulfur or mixtures thereof. The present invention further discloses a method of depositing tin or a tin alloy onto a surface of a substrate. The tin plating bath is particularly suitable to be used in the electronics and semiconductor industry.

The present invention concerns a tin plating bath comprising tin ions; titanium ions as reducing agent suitable to reduce tin ions to metallic tin; and at least one compound selected from the group consisting sulfites, dithionites, thiosulfates, tetrathionates, polythionates, disulfites, sulfides, disulfide, polysulfide, elemental sulfur or mixtures thereof. The present invention further discloses a method of depositing tin or a tin alloy onto a surface of a substrate. The tin plating bath is particularly suitable to be used in the electronics and semiconductor industry.

A method of performing an immersion tin process in the production of a component carrier is provided which includes immersing at least a part of a copper surface of the component carrier in a composition containing Sn(II) in an immersion tin unit, while passing a non-oxidizing gas through the immersion tin unit, wherein at least part of the non-oxidizing gas is recycled. In addition, an apparatus for performing an immersion tin process in the production of a component carrier, a method of performing a copper plating process in the production of a component carrier and an apparatus for performing a copper plating process in the production of a component carrier are provided.

The present invention concerns a tin plating bath comprising tin ions; at least one complexing agent selected from the group consisting of pyrophosphate ions, linear polyphosphate ions and cyclic polyphosphate ions and a nitrogen and sulfur containing stabilizing additive and titanium (III) ions as a reducing agent suitable to reduce tin ions to metallic tin. The present invention further discloses a method of depositing tin or a tin alloy onto a surface of a substrate. The tin plating bath is particularly suitable to be used in the electronics and semiconductor industry.

The present invention concerns a tin plating bath comprising tin ions; at least one complexing agent selected from the group consisting of pyrophosphate ions, linear polyphosphate ions and cyclic polyphosphate ions and a nitrogen and sulfur containing stabilizing additive and titanium (III) ions as a reducing agent suitable to reduce tin ions to metallic tin. The present invention further discloses a method of depositing tin or a tin alloy onto a surface of a substrate. The tin plating bath is particularly suitable to be used in the electronics and semiconductor industry.