A method for electroless deposition of aluminum on a substrate includes: activating the substrate; providing an aluminum ionic liquid; adding a reducing agent and an additive to the aluminum ionic liquid to form an electroless plating composition, wherein the additive may include a catalyst, an alloying element, or a combination thereof; and immersing the substrate in the electroless plating composition to have an aluminum layer deposited on the substrate. An article includes the electroless deposited aluminum layer.

A plating-pattern plate is configured to transfer, to a substrate, a transfer pattern formed by plating. The plating-pattern plate includes a base body and transfer parts disposed on the base body. Each of the transfer parts has a transfer surface configured to have the transfer pattern to be formed on the transfer surface by plating. The transfer parts are disposed electrically independent of one another on the base body. The plating-pattern plate provides a fine conductive pattern with stable quality.

This application relates to a metal coating method for plastic outer part requiring robustness. In the metal coating method, first, provide a plastic outer part as a motion assistance tool. Thereafter, a cold plasma treatment is performed to introduce a polar functional group to a surface of the plastic outer part by treating the plastic outer part with cold plasma. Next, a metal coating layer is formed on the surface of the plastic outer part treated with the cold plasma by an electroless plating method. Thereafter, an adhesive strength improvement process of improving an adhesive strength between the metal coating layer and the plastic outer part to 1,000 g/cm.sup.2 or more by heat treatment of the plastic outer part with the metal coating layer thereon is performed.

The present invention relates to a multi-layered elastomer article and to a method for its manufacturing. The multi-layered article made of an elastomeric composition [composition (C)] comprising at least one elastomer, said article having at least one surface [surface (S)] comprising: —nitrogen-containing groups [groups (N)] and —at least one layer [layer (L1)] adhered to said surface (S) comprising at least one metal compound [compound (M)].

A partially plated plastic product includes a first base member and a second base member that are made of different plastic materials. The first base member includes a first corner portion having a curved wall surface. The second base member includes a second corner portion. The first and second corner portions are located on a front side of the product. The first and second base members are adjacent to each other at least at the first corner portion and the second corner portion. Only one of the first and second base members includes a metal coating film formed on a region of an outer surface of the base member with which the other base member is not in contact. The second corner portion includes a groove forming portion. The groove forming portion forms a groove between itself and at least the curved wall surface of the first corner portion.

Method and apparatus for producing metal-coated optical fiber involves providing a length of optical fiber having a glass fiber with or without a carbon layer surrounded by a liquid-soluble polymeric coating. The optical fiber is passed through a series of solution baths such that the fiber will contact the solution in each bath for a predetermined dwell time, the series of solution baths effecting removal of the polymer coating and subsequent electroless plating of metal on the glass fiber. The optical fiber is collected after metal plating so that a selected quantity of the metal-coated optical fiber is gathered, Preferably, the glass fiber passes through the series of solution baths without contacting anything except for the respective solution in each.

An electroless semiconductor bonding structure, an electroless plating system and an electroless plating method of the same are provided. The electroless semiconductor bonding structure includes a first substrate and a second substrate. The first substrate includes a first metal bonding structure disposed adjacent to a first surface of the first substrate. The second substrate includes a second metal bonding structure disposed adjacent to a second surface of the second substrate. The first metal bonding structure connects to the second metal bonding structure at an interface by electroless bonding and the interface is substantially void free.

An environmentally friendly method of coating copper nanowires to reduce oxidation and/or increase electrical/thermal conductivity of the copper nanowires. In one embodiment, a method for coating copper nanowires includes preparing a first solution including a dipolar aprotic organic compound, adding copper nanowires to the first solution under stirring while maintaining the first solution at a pre-determined temperature, preparing a second solution including an oxidation resistant metal, coating the copper nanowires in the oxidation resistant metal by adding the second solution to the first solution under stirring and while maintaining the first solution at the pre-determined temperature.

A method for fabricating a sensor includes coating an end-polished sapphire fiber with aluminum to produce a sapphire fiber having an aluminum coating, anodizing the aluminum coating to produce an aluminum oxide coating, and removing the aluminum oxide coating from a distal end of the sapphire fiber.

Shielding coatings are applied to polymer substrates for selective metallization of the substrates. The shielding coatings include a primer component and a hydrophobic top coat. The primer is first applied to the polymer substrate followed by application of the top coat component. The shielding coating is then selectively etched to form an outline of a desired current pattern. A catalyst is applied to the patterned polymer substrate followed by electroless metal plating in the etched portions. The portions of the polymer substrate which contain the shielding coating inhibit electroless metal plating. The primers contain aromatic heterocyclic compounds and the top coat contains hydrophobic alky organic compounds.