A method for forming a metal film includes forming an oxide layer on a to-be-treated surface of a to-be-treated object by bringing the to-be-treated surface into contact with a reaction solution containing fluorine and an oxide precursor, removing fluorine in the oxide layer, supporting a catalyst on the oxide layer by bringing the oxide layer into contact with a catalyst solution, and depositing a metal film on the oxide layer by bringing the oxide layer into contact with an electroless plating liquid.

A method for plating a work piece includes forming a work piece, where the work piece includes first and second segments that are electrically isolated. The first segment is connected in a first circuit and the second segment is connected in a second circuit. The first circuit may include a first power source and the second circuit may include a second power source. The work piece and the first and second segments may be disposed in a common solution, and current may be applied in the first circuit and the second circuit to create first and second metal surfaces. The first and second metal surfaces may be made from the same base metal. The first and second metal surfaces may be created simultaneously, with the work piece and the first and second segments disposed in a common solution.

Methods/structures of forming substrate tap structures are described. Those methods/structures may include forming a plurality of conductive interconnect structures on an epitaxial layer disposed on a substrate, wherein individual ones of the plurality of conductive interconnect structures are adjacent each other, forming a portion of a seed layer on at least one of the plurality of conductive interconnect structures, and forming a conductive trace on the seed layer.

The present invention relates to a surface modifier for electrolytic nickel plating including at least one carboxyl group-containing compound and a nickel electroplating solution including the surface modifier. The use of the nickel electroplating solution according to the present invention enables efficient formation of a plated nickel layer with high surface roughness and mattness even without performing strong electrolysis, unlike in the prior art.

The present invention pertains to a multilayer tubular article, to processes for the manufacture of said multilayer tubular article and to uses of said multilayer tubular article in upstream applications for conveying hydrocarbons from a well to a floating off-shore unit via a bottom platform.

A coating agent for forming an oxide film; a method for producing an oxide film; and a method for producing a metal-plated structure, where the stability of the coating agent can be enhanced, and an oxide film which can be plated and has high adhesion to a substrate can be easily formed. The coating agent for forming an oxide film is a liquid coating agent, essentially contains titanium atoms, and optionally contains silicon atoms and copper atoms, wherein the ratio of the sum of the titanium atoms and copper atoms to the silicon atoms is 1:0-3:2. The method for producing an oxide film includes applying the coating agent to a substrate and heating to form an oxide film. The method for producing a metal-plated structure includes: a metal-film-forming step for forming a metal film on the oxide film; and a baking step for baking the metal film.

Two-dimensional conductive nanoparticles may facilitate preparation of metal coatings prepared via electroless plating. Articles having a metal coating may comprise: a polymer body, and a metal coating on at least a portion of an outer surface of the polymer body. The metal coating comprises a plating metal and overlays a plurality of two-dimensional conductive nanoparticles and a catalyst metal.

A plating method can improve adhesivity with a substrate. The plating method of performing a plating process on the substrate includes forming a vacuum-deposited layer 2A on the substrate 2 by performing a vacuum deposition process on the substrate 2; forming an adhesion layer 21 and a catalyst adsorption layer 22 on the vacuum-deposited layer 2A of the substrate 2; and forming a plating layer stacked body 23 having a first plating layer 23a and a second plating layer 23b which function as a barrier film on the catalyst adsorption layer 22 of the substrate 2. By forming the vacuum-deposited layer 2A, a surface of the substrate 2 can be smoothened, so that the vacuum-deposited layer 2A serving as an underlying layer can improve the adhesivity.

Provided is a copper foil provided with a carrier in which the laser hole-opening properties of the ultrathin copper layer are good and which is suitable for producing a high-density integrated circuit substrate. A copper foil provided with a carrier having, in order, a carrier, an intermediate layer, and an ultrathin copper layer, wherein the specular gloss at 60° in an MD direction of the intermediate layer side surface of the ultrathin copper layer is 140 or less.

The present invention provides a plating method capable of easily performing various decorative plating processes. The plating method includes a bulge forming process of forming a bulge on an object to be plated by ejecting ink drops of first UV-curable ink from an inkjet head such that the ejected ink drops land on the object, and a plating process of plating the object having the bulge formed thereon, after the bulge forming process. Also, in the bulge forming process, the bulge is formed such that a second surface of the bulge to be plated has surface roughness different from that of a first surface of the object to be plated.