Abstract: A method for forming a conductive layer pattern by selectively depositing droplets containing conductive material onto a porous receiving layer. Much of the conductive material is left on the surface for forming wiring patterns but some of it permeates the pockets or voids in the receiving layer and can be used, for example, to provide interlayer connections in laminated wiring boards. Preferably, the conductive material is provided by fine conductive particles, organometallic compounds or mixtures thereof.

Abstract: A method of forming a metal fine particle pattern including forming a polymerization initiation layer on a support, wherein a polymer which has, in its side chain, a cross-linking group and a functional group having the ability to initiate polymerization is fixed by a cross-linking reaction, forming a graft polymer region in a pattern on the surface of the polymerization initiation layer, wherein the graft polymer layer has the ability to contain a metal ion or a metal salt, adding a metal ion or a metal salt to the graft polymer layer, and thereafter reducing the metal ion or a metal ion in the metal salt to form a metal fine particle dispersion region; and a method of forming an electroconductive pattern using the method of forming a metal fine particle pattern.

Abstract: A method making possible the production of an injection molded conductor carrying means composed of a first supporting substrate and a second supporting substrate. The first supporting substrate comprises a basically metallizeable plastic material and the second supporting substrate a basically non-metallizeable plastic material. However the plastic material of the second supporting substrate is able to be activated by a laser beam. The laser activation produces a metallization pattern on it and such pattern is connected with uncovered areas of the first supporting substrate, following which a common treatment takes place which results in an electrical conductor arrangement being produced. The invention furthermore relates to a conductor carrying means produced by the method.

Abstract: Methods and apparatuses for assembling a structure onto a substrate. A method according to one aspect of the invention includes dispensing a slurry onto a substrate wherein the slurry includes a first plurality of elements, each of which is designed to mate with a receptor region on said substrate and each of which comprises a functional element. The method further includes dispensing in a flow having a first direction a slurry onto a substrate, wherein the slurry includes a fluid.

Abstract: A method for surface treatment includes: a first step in which a surface treatment apparatus 1 and a substrate 10 in a state where a front surface 102 of the substrate 10 faces the surface treatment apparatus 1 are conveyed to the inside of a decompression chamber to decompress a plurality of concave portions 32 (enclosed spaces); a second step in which the surface treatment apparatus 1 and the substrate 10 are brought out from the inside of the decompression chamber to environment under atmospheric pressure in a state where the substrate 10 is being attracted to the surface treatment apparatus 1 with the use of a difference between negative pressure inside the concave portions 32 and atmospheric pressure; and a third step in which the surface treatment is carried out to a back surface 101 of the substrate 10 with the substrate 10 being attracted by the surface treatment apparatus 1.

Abstract: Disclosed is a process for applying a kinetic spray coating of powder particles onto a substrate covered in a plastic-type material without first removing the plastic-type material. In one use of the process a mask is used to enable a single kinetic spray pass to both remove the plastic covering and bind particles having average nominal diameters of from 60 to 250 microns to the underlying substrate. In another use of the process the particles have an average nominal diameter of from 250 to 1400 microns and the use of a mask is optional because the particles can penetrate the plastic material and bind directly to the substrate. The process finds special use in forming electrical connections or solderable pads anywhere along the length of a flexible circuit.

Abstract: A substrate is patterned by forming an indent region 8 in the surface 10 of a substrate 4 and depositing a liquid material onto the surface 10 at selected locations adjacent to the indent region 8. The liquid material spreads over the surface to an edge of the indent region, at which point further spreading is controlled by the effective enhancement of the contact angle of the liquid material relative to the surface as provided by the indent region.

Abstract: A method of making a circuitized substrate such as a laminate chip carrier in which a polymer, e.g., Teflon, is used as a dielectric layer and a promotion adhesion layer of a polymer is used to securely adhere a conductive layer thereto which is deposited by plating. The resulting product is thus able to provide extremely narrow conductive circuitry for subsequent connections, e.g., to a semiconductor chip. Electroless plating is the preferred plating method with the dielectric immersed in a solution of conductive monomers, e.g., pyrrole monomer, the solution also possibly containing a seed material such as palladium-tin.