A printed circuit board includes an electrically conductive layer and a dielectric layer including a polymer. The polymer includes at least one of a carbon layer structure and a carbon-like layer structure.

A transparent display panel, and a method of manufacturing the transparent display panel are discussed. The transparent display panel according to one embodiment includes a substrate; a driving element formed in a display pixel area on the substrate; a wiring electrode formed in the display pixel area and connected to the driving element; and a transparent wiring electrode formed in a transmissive area on the substrate, the transparent wiring electrode being extended to connect to the wiring electrode in the display pixel area.

Method for manufacturing segmented electro-optic display backplanes includes (a) providing a laminate comprising an insulating layer having opposite first and second surfaces and a conductive metal layer having opposite first and second surfaces (the insulating layer second surface is superposed on the conductive metal layer first surface); (b) applying laser energy from a first laser source passing through the insulating layer onto selected portions of conductive metal layer first surface to cause adjacent portions of the insulating layer to be pyrolyzed to form conductive carbon regions; (c) applying laser energy from a second laser source on the insulating layer first surface to pyrolyze selected portions thereof into conductive carbon segments electrically isolated from each other by other portions of the insulating layer. The conductive carbon regions in the insulating layer form vias between each of the conductive carbon segments and one of the selected portions of the conductive metal layer.

The present invention relates to an LDS-active additive for LDS plastics, to a polymer composition comprising an additive of this type, and to an article having metallised conductor tracks in which a polymeric basic body of the article or a polymeric coating on a basic body comprises an LDS additive of the said type.

A flake-less molecular ink suitable for printing (e.g. screen printing) conductive traces on a substrate has 30-60 wt % of a C.sub.8-C.sub.12 silver carboxylate or 5-75 wt % of bis(2-ethyl-1-hexylamine) copper (II) formate, bis(octylamine) copper (II) formate or tris(octylamine) copper (II) formate, 0.1-10 wt % of a polymeric binder (e.g. ethyl cellulose) and balance of at least one organic solvent. Conductive traces formed with the molecular ink are thinner, have lower resistivity, have greater adhesion to a substrate than metal flake inks, have better print resolution and are up to 8 times less rough than metal flake inks. In addition, the shear force required to remove light emitting diodes bonded to the traces using Loctite 3880 is at least 1.3 times stronger than for commercially available flake-based inks.

A printed circuit board includes an electrically conductive layer and a dielectric layer including a polymer, wherein the polymer includes metallic particles.

Synthetic polymers in membrane or film or bulk form (continuous or micro-/nanostructured, supported or self-standing), if exposed to solutions of alkali hydroxides, can be carbonised by CO.sub.2 laser writing under ambient conditions (without any inert gas in contact with the material), to obtain electrically conductive tracks and patterns.

Thermally induced graphene sensing circuitry and methods for producing circuits from such thermally induced circuits are disclosed along with applications to hydrocarbon exploration and production, and related subterranean activities. The thermally induced graphene circuitry advantageously brings electrically interconnections otherwise absent on oilfield service tools, enabling components and tools to become smart.