The present invention refers to a new type of transport roller providing a modified surface to provide improved transport properties for new substrates. Furthermore, it refers to horizontal transport systems beneficially utilizing such transport rollers, especially for providing retaining roller pairs. Additionally, the present invention refers to a treatment device containing such transport roller or horizontal transport system. Furthermore, it refers to a method for treating a substrate and the use of such transport roller.

A circuit board includes a glass substrate having a first surface and a second surface facing away from the first surface; a first coil wiring pattern formed on the first surface and a second coil wiring pattern formed on the second surface, the first and second coil wiring patterns constituting part of a coil; a through hole extending through a predetermined portion of the glass substrate from an end of the first coil wiring pattern to an end of the second coil wiring pattern; a through hole inner conductive surface formed on the inner side of the through hole, the first and second coil wiring patterns and the through hole inner conductive surface constituting the coil wound around a direction perpendicular to an axis of the through hole and to a direction in which the first and second coil wiring patterns extend.

A method of preparing a non-conductive substrate to allow metal plating thereon. The method includes the steps of a) contacting the non-conductive substrate with a conditioner comprising a conditioning agent; b) applying a carbon-based dispersion to the conditioned substrate, wherein the carbon-based dispersion comprises carbon or graphite particles dispersed in a liquid solution; and c) etching the non-conductive substrate. The etching step is performed before the liquid carbon-based dispersion dries on the non-conductive substrate.

Forming, in a printed-wiring board, a via sufficiently filled without residual smear, for use in an insulating layer and the size of the via to be formed. A via of a printed-wiring board comprises a first filling portion which fills at least a center portion of a hole, and a second filling portion which fills a region of the hole that is not filled with the first filling portion. An interface which exists between the second and first filling portions, or an interface which exists between the second filling portion and an insulating layer and the first filling portion has the shape of a truncated cone comprising a tapered surface which is inclined to become thinner from a first surface toward a second surface, and an upper base surface which is positioned in parallel to the second surface and closer to the first surface than to the second surface.

A recess or through-hole forming method for forming a substrate with a recess or a through-hole along a thickness direction of the substrate, the method including: a modified region forming step of applying a laser beam of such a wavelength as to be transmitted through the substrate to the substrate, with a focal region of the laser beam positioned inside the substrate, to form a column-shaped modified region which is exposed to a surface of the substrate and extends along the thickness direction of the substrate; and an etching step of etching the modified region to form the substrate with the recess or the through-hole, after the modified region forming step is performed.

A composite circuit board includes a composite circuit board unit, a first solder mask formed on a first metal protection layer of the composite circuit board unit, and a second solder mask formed on a second metal protection layer of the composite circuit board unit. Two ends of a first outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a first window. Two ends of a second outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a second window.

A method of manufacturing a printed circuit board includes providing an insulating layer, forming a plating seed layer on the insulating layer, forming a first circuit pattern on the plating seed layer and a second circuit pattern on the first circuit pattern, and forming a top metal layer on the second circuit pattern. The second circuit pattern can be thinner than the first circuit pattern, and the top metal layer can be wider than the second circuit pattern.

A method of preparing a non-conductive substrate to allow metal plating thereon. The method includes the steps of a) contacting the non-conductive substrate with a conditioner comprising a conditioning agent; b) applying a carbon-based dispersion to the conditioned substrate, wherein the carbon-based dispersion comprises carbon or graphite particles dispersed in a liquid solution; and c) etching the non-conductive substrate. The etching step is performed before the liquid carbon-based dispersion dries on the non-conductive substrate.

A method of manufacturing a wiring board, includes forming an interconnect layer on a first insulating layer, roughening a surface of the interconnect layer, not in contact with the first insulating layer, to form concavo-convex portions, forming a bond enhancing film on the concavo-convex portions, partially removing the bond enhancing film, using an acid solution, and forming a second insulating layer on the first insulating layer, to cover the interconnect layer.

A circuit board is formed from a catalytic laminate having a resin rich surface with catalytic particles dispersed below a surface exclusion depth. The catalytic laminate is subjected to a drilling and blanket surface plasma etch operation to expose the catalytic particles, followed by an electroless plating operation which deposits a thin layer of conductive material on the surface. A photo-masking step follows to define circuit traces, after which an electro-plating deposition occurs, followed by a resist strip operation and a quick etch to remove electroless copper which was previously covered by photoresist.