A printed circuit board according to an embodiment of the present disclosure includes a base film having an insulating property, and a conductive pattern that is stacked on at least one surface of the base film and that includes a plurality of wiring parts arranged in parallel. The plurality of wiring parts have an average width of 5 μm or more and 15 μm or less. The plurality of wiring parts have an electroless plating layer and an electroplating layer stacked on the electroless plating layer. A void density at an interface between the electroless plating layer and the electroplating layer in a section of the plurality of wiring parts in a thickness direction is 0.01 μm.sup.2/μm or less.

A printed circuit board according to an embodiment of the present disclosure includes a base film having an insulating property, and a conductive pattern that is stacked on at least one surface of the base film and that includes a plurality of wiring parts arranged in parallel. The plurality of wiring parts have an average width of 5 μm or more and 15 μm or less. The plurality of wiring parts have an electroless plating layer and an electroplating layer stacked on the electroless plating layer. A void density at an interface between the electroless plating layer and the electroplating layer in a section of the plurality of wiring parts in a thickness direction is 0.01 μm.sup.2/μm or less.

A method of creating a selectively plated three-dimensional thermoplastic part. The method includes the steps of: a) providing a film of uncured polycarbonate film having a hardcoated layer on a first surface thereof; b) selectively catalyzing the polycarbonate film by depositing a catalyst in a desired pattern on the first surface of the polycarbonate film; c) thermoforming the polycarbonate film to form a three-dimensional polycarbonate film; d) UV-curing the hardcoated polycarbonate film by irradiating the film with UV rays; e) molding the hardcoated polycarbonate film to produce a three-dimensional molded part comprising the hardcoated polycarbonate film; f) activating the selectively catalyzed hardcoated polycarbonate film; and g) plating a metal layer on the catalyzed portions of the hardcoated polycarbonate film, wherein the plated metal only deposits on the catalyzed portions of the hardcoated polycarbonate film.

The instant disclosure provides a method for manufacturing an electroless plating substrate and a method for forming a metal layer on a surface of a substrate. The method for preparing the electroless plating substrate includes: providing a substrate; attaching a self-adsorbed catalyst composition to a surface of the substrate; and performing an electroless metal deposition for forming an electroless metal layer on the surface of the substrate. The self-adsorbed catalyst composition includes a colloidal nanoparticle and a silane compound. The colloidal nanoparticle includes a palladium nanoparticle and a capping agent enclosing the palladium nanoparticle. The silane compound has at least one amino group to interact with the colloidal nanoparticle. A covalent bond between the silane compound and the surface of the substrate is formed through the at least one silane group of the silane compound. The colloid nanoparticle has a particle size ranging from 5 to 10 nanometers.

A new method capable of forming a circuit by performing metal plating on a desired portion on a substrate through a small number of steps regardless of the kind of the substrate. A method for forming a circuit on a substrate characterized in that when forming a circuit by plating on a substrate, the method includes steps of applying a coating film containing a silicone oligomer and a catalyst metal onto the substrate, and thereafter, performing an activation treatment of the catalyst metal in the coating film to make the catalyst metal exhibit autocatalytic properties, and then, performing electroless plating.

A method for selective metallization includes: selectively adsorbing catalytic nanoparticles onto an imprint mold to form a selectively adsorbed catalytic nanoparticle (SACN) mold; using the SACN mold in an imprinting process to synchronously transfer a pattern and the catalytic nanoparticles onto a film; separating the film from the SACN mold; and selectively depositing metal onto the film based on the pattern transferred to the film.

A method of producing an electroconductive substrate including a base material, and an electroconductive pattern disposed on one main surface side of the base material includes: a step of forming a trench including a bottom surface to which a foundation layer is exposed, and a lateral surface which includes a surface of a trench formation layer, according to an imprint method; and a step of forming an electroconductive pattern layer by growing metal plating from the foundation layer which is exposed to the bottom surface of the trench.

The instant disclosure provides a self-adsorbed catalyst composition, a method for preparing the self-adsorbed catalyst composition and a method for manufacturing an electroless plating substrate. The self-adsorbed catalyst composition includes colloidal nanoparticles and a silane compound. The colloidal nanoparticles include palladium nanoparticles and capping agents enclosing the palladium nanoparticles. The silane compound has at least an amino group, and an interaction is established between the amino group of the silane compound and the colloidal nanoparticle.

The instant disclosure provides a method for manufacturing an electroless plating substrate and a method for forming a metal layer on a surface of a substrate. The method for preparing the electroless plating substrate includes: providing a substrate; attaching a self-adsorbed catalyst composition to a surface of the substrate; and performing an electroless metal deposition for forming an electroless metal layer on the surface of the substrate. The self-adsorbed catalyst composition includes a colloidal nanoparticle and a silane compound. The colloidal nanoparticle includes a palladium nanoparticle and a capping agent enclosing the palladium nanoparticle. The silane compound has at least one amino group to interact with the colloidal nanoparticle. A covalent bond between the silane compound and the surface of the substrate is formed through the at least one silane group of the silane compound. The colloid nanoparticle has a particle size ranging from 5 to 10 nanometers.

A method of producing an electroconductive substrate including a base material, and an electroconductive pattern disposed on one main surface side of the base material includes: a step of forming a trench including a bottom surface to which a foundation layer is exposed, and a lateral surface which includes a surface of a trench formation layer, according to an imprint method; and a step of forming an electroconductive pattern layer by growing metal plating from the foundation layer which is exposed to the bottom surface of the trench.