An object is to coat a target position on a substrate with a dense film. In order to achieve the object, while a substrate on which a base containing a coating material is formed is transported, an auxiliary agent is applied to the substrate, and then a main agent containing a coating material is applied to the substrate to react the main agent with the auxiliary agent, so that a portion on the substrate where the base is formed is coated with the coating material.

A method of coating an antimicrobial conductive metal layer on a non-conductive surface of articles with novel chemistry and methods with just a few process steps consisting of contacting the chemistries at room temperature for short durations is disclosed. The methodology is environmentally friendly, non-toxic aqueous bath of different salt compositions for providing uniform anti-microbial metal coating on the articles. The cost-effective methodology can be used on a wide variety of non-conductive surfaces such as glass, fibers, textiles, ceramic, plastic, foam and so on.

Materials and methods for coating an electrochemically active electrode material for use in a lithium-ion battery are provided. In one example, an electrochemically active electrode material comprises: a polymer coating applied directly to an exterior surface of the electrochemically active electrode material; a metal plating catalyst adhered to the continuous polymer; and a continuous metal coating that completely covers the metal catalyst and continuous polymer coating. The electrochemically active electrode material may comprise a powder comprising one or more secondary particles, and the polymer and metal coatings may be applied to exterior surfaces of these secondary particles.

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.

The invention relates to medical devices and, more in particular, to medical devices suitable for use as stents that contain an antimicrobial coating and, optionally, a drug customized to patients requirements. The invention also relates to methods for obtaining devices having the above features.

A package which comprises a first encapsulant configured so that electrically conductive material is plateable thereon, and a second encapsulant configured so that electrically conductive material is not plateable thereon.

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.

A method of manufacturing a package, comprising embedding the semiconductor chip with an encapsulant comprising a transition metal in a concentration in a range between 10 ppm and 10,000 ppm; selectively converting of a part of the transition metal, such that the electrical conductivity of the encapsulant increases; and plating the converted part of the encapsulant with an electrically conductive material.

A method of manufacturing a metal fabric or membrane, the method comprises providing an ink comprising a plurality of semiconductor particles disposed in a first solvent. The method comprises applying the ink to a fabric or membrane to obtain a fabric or membrane comprising a plurality of semiconductor particles. Finally, the method comprises contacting the fabric or membrane comprising the plurality of semiconductor particles with a deposition solution comprising a second solvent, an autocatalytic agent, and metal cations to thereby cause a reaction to occur such that the metal cations are reduced and at least partially displace the semiconductor particles, to thereby provide a metal fabric or membrane.

A plating method includes preparing a substrate having a surface including an adhesive material portion made of a material to which a catalyst easily adheres and a non-adhesive material portion to which the catalyst is difficult to attach; imparting the catalyst to the substrate by supplying a catalyst solution onto the substrate; removing, by supplying a catalyst removing liquid containing a reducing agent onto the substrate, the catalyst from the non-adhesive material portion while allowing the catalyst to be left on a surface of the adhesive material portion; and forming a plating layer selectively on the adhesive material portion by supplying a plating liquid onto the substrate.