An exemplary embodiment of the present invention comprises: 1) forming a crystalline transparent conducting layer on a substrate; 2) forming an amorphous transparent conducting layer on the crystalline transparent conducting layer; 3) forming at least one pattern open region so as to expose a part of the crystalline transparent conducting layer by patterning the amorphous transparent conducting layer; and 4) forming a metal layer in the at least one pattern open region.

A process of producing a conducting material suitable for being filled in TSVs for LSI chip 3D package, etc. includes that a solution containing a monomer that provides a conducting polymer, anions, and metal ions such as Ag.sup.+ or Cu.sup.2+ is irradiated with ultraviolet radiation or light having the energy necessary for exciting electrons up to an energy level capable of reducing the metal ions to precipitate a conducting polymer/metal composite. This enables an electrical conductor of high electrical conductivity to be precipitated faster than could be achieved by conventional processes.

A method for forming a three-dimensional object with at least one conductive trace comprises providing an intermediate structure that is generated (e.g., additively or subtractively generated) from a first material in accordance with a model design of the three-dimensional object. The intermediate structure may have at least one predefined location for the at least one conductive trace. The model design includes the at least one predefined location. Next, the at least one conductive trace may be generated adjacent to the at least one predefined location of the intermediate structure. The at least one conductive trace may be formed of a second material that has an electrical and/or thermal conductivity that is greater than the first material.

The invention relates to a composition and a process for the deposition of conductive polymers on dielectric substrates. In particular, the invention relates to a composition for the formation of electrically conductive polymers on the surface of a dielectric substrate, the composition comprising at least one polymerizable monomer which is capable to form a conductive polymer, an emulsifier and an acid, characterized in that the composition comprises at least one metal-ion selected from the group consisting of lithium-ions, sodium-ions, aluminum-ions, beryllium-ions, bismuth-ions, boron-ions, indium-ions and alkyl imidazolium-ions.

The invention relates to a layered structure (10) comprising the following layers: a) a first substrate layer (2), wherein the first substrate layer (2) has a first surface (4) and a second surface (6) and is configured as a dielectric; b) a first electrically conductive layer (8) which overlaps at least in part the first substrate layer (2) at least on the first surface (4) of the first substrate layer (2), wherein the first electrically conductive layer (8) comprises an electrically conductive polymer, wherein the first electrically conductive layer (8) has at least one first part region (18) and at least one further part region (20), wherein the at least one first part region (18) has a higher bonding strength to the substrate layer (2) than to the at least one further part region (20).

In a substrate like a printed circuit board comprising an insulator and a copper layer laminated on part of the insulator, said insulator outer surface and said copper layer outer surface are simultaneously subjected to a process (1) comprising treatment with an alkali metal hydroxide solution, a process (2) comprising treatment with an alkaline aqueous solution containing an aliphatic amine, a process (3) comprising treatment with an alkaline aqueous solution having a permanganate concentration of 0.3 to 3.5 wt % and a pH of 8 to 11, a process (4) comprising treatment with an acidic microemulsion aqueous solution containing a thiophene compound and an alkali metal salt of polystyrenesulphonic acid, and a process (5) comprising copper electroplating, which are implemented sequentially.

Discussed generally herein are methods and devices for altering an effective series resistance (ESR) of a component. A device can include a substrate including electrical connection circuitry therein, a first via hole through a first surface of the substrate and contiguous with the electrical connection circuitry, a first conductive polymer with a resistance greater than a resistance of the electrical connection circuitry filling the first via hole, and a component electrically coupled to the first conductive polymer.

The disclosed technology provides micro-assembled micro-LED displays and lighting elements using arrays of micro-LEDs that are too small (e.g., micro-LEDs with a width or diameter of 10 ?m to 50 ?m), numerous, or fragile to assemble by conventional means. The disclosed technology provides for micro-LED displays and lighting elements assembled using micro-transfer printing technology. The micro-LEDs can be prepared on a native substrate and printed to a display substrate (e.g., plastic, metal, glass, or other materials), thereby obviating the manufacture of the micro-LEDs on the display substrate. In certain embodiments, the display substrate is transparent and/or flexible.

A process for producing an electrically conductive, crosslinkable silicone elastomer composition includes an electrically conductive, crosslinkable silicone elastomer composition that contains 0.5% to 3.0% by weight of conductivity carbon black, 0.1% to 3.0% by weight of multiwalled carbon nanotubes (MWCNTs), and no solvent. In the case of one-component systems, all components are mixed in one or more steps and subsequently a pressure filtration through a metal fabric having a mesh size of at most 200 m is carried out. In the case of two-component systems, in each case only the components of an A or a B composition are mixed in one or more steps and subsequently in each case a pressure filtration of the A or the B composition through a metal fabric having a mesh size of at most 200 m is carried out.

A circuit board includes a flexible board, a composite film, and a copper layer. The composite film is formed on the flexible board and defines at least one through hole. The composite film includes a base layer having an active surface, and a conductive layer formed by coated a conductive polymer on the active surface. The conductive polymer is made by a mixture comprising liquid crystal monomers, a silver complex, an initiator, and a catalytic agent, and a solvent, the mixture is heated to undergo atom transfer radical polymerization. The copper layer covers the conductive layer and an inner wall of each of the at least one through hole. The copper layer is electrically connected to the flexible substrate by the through hole.