One aspect relates to a method for the manufacture of a medical electrode, including: (i) providing a substrate; (ii) applying a composition onto the substrate, wherein the composition comprises (a) a non-aqueous solvent and (b) an organic precious metal complex compound that is dissolved in the solvent; (iii) heating the composition and thereby forming a precious metal layer on the substrate, wherein the solubility of the organic precious metal complex compound in propylene glycol mono-propyl ether at 25° C. and 1013 hPa is at least 1 mass percent, or at least 2, 3, 4, 5 or 10 mass percent, in relation to the total mass of the composition.

One aspect relates to a method for the manufacture of a medical electrode, including: (i) providing a substrate; (ii) applying a composition onto the substrate, wherein the composition comprises (a) a non-aqueous solvent and (b) an organic precious metal complex compound that is dissolved in the solvent; (iii) heating the composition and thereby forming a precious metal layer on the substrate, wherein the solubility of the organic precious metal complex compound in propylene glycol mono-propyl ether at 25° C. and 1013 hPa is at least 1 mass percent, or at least 2, 3, 4, 5 or 10 mass percent, in relation to the total mass of the composition.

A method of manufacturing transition metal chalcogenide thin films, includes the operations of forming a transition metal chalcogenides precursor on a substrate, and irradiating light onto the transition metal chalcogenides precursor. The transition metal chalcogenides precursor includes an amine-based ligand.

A method of manufacturing transition metal chalcogenide thin films, includes the operations of forming a transition metal chalcogenides precursor on a substrate, and irradiating light onto the transition metal chalcogenides precursor. The transition metal chalcogenides precursor includes an amine-based ligand.

A method for patterning a metal layer on a substrate is disclosed. Furthermore, a kit comprising a first composition comprising a reducing agent and a second composition comprising a metal salt, and an article comprising a substrate in contact with a metal layer are also disclosed.

A copper-based ink contains copper acetate, 3-dimethylamino-1,2-propanediol and a silver salt. The ink may be coated on a substrate and decomposed on the substrate to form a conductive copper coating on the substrate. The ink provides micron-thick traces and may be screen printed and thermally sintered in the presence of up to about 500 ppm of oxygen or photo-sintered in air to produce highly conductive copper features. Sintered copper traces produced from the ink have improved air stability, and have improved sheet resistivity for 5-20 mil wide screen-printed lines with excellent resolution.

A flexible emitting light device production apparatus of the present disclosure includes: a stage (520) for supporting a flexible emitting light supporting substrate (10), the flexible display supporting substrate including a glass base (11) and a synthetic resin film (12) provided on the glass base; a polisher head (535) configured to approach a selected region of a surface (12s) of the synthetic resin film (12) and polish the region so that a polish recess (12c) is formed in the surface (12s); and a repair head (536) for supplying a liquid material (20a) to the polish recess (12c) formed in the surface (12s) of the synthetic resin film (12) and heating the liquid material (20a), thereby forming a sintered layer (20) from the liquid material (20a).

The invention relates to a process for producing a structured shaped body or a layer of this type from a precursor of a metal oxide or mixed oxide selected from compounds of metals selected from among magnesium, strontium, barium, aluminum, gallium, indium, silicon, tin, lead and the transition metals. The process includes at least the following steps: (a) dissolving at least one compound of the at least one metal in an organic solvent and/or exchanging a ligand of the one or more dissolved metallic compounds for a stabilizing ligand, (b) adding a ligand that has at least one photochemically polymerizable group and at least one such group that allows a stable complex formation to the solution and forming a sol with or from the product of this reaction (precursor), (c) applying the sol on a substrate, and (d) exposing the sol anisotropically in such a way that a polymerization of the photochemically polymerizable groups takes place in the exposed areas.

The invention relates to a process for producing a structured shaped body or a layer of this type from a precursor of a metal oxide or mixed oxide selected from compounds of metals selected from among magnesium, strontium, barium, aluminum, gallium, indium, silicon, tin, lead and the transition metals. The process includes at least the following steps: (a) dissolving at least one compound of the at least one metal in an organic solvent and/or exchanging a ligand of the one or more dissolved metallic compounds for a stabilizing ligand, (b) adding a ligand that has at least one photochemically polymerizable group and at least one such group that allows a stable complex formation to the solution and forming a sol with or from the product of this reaction (precursor), (c) applying the sol on a substrate, and (d) exposing the sol anisotropically in such a way that a polymerization of the photochemically polymerizable groups takes place in the exposed areas.

A manufacturing method of a wire grid polarizer is provided, including: setting pattern data, where the pattern data correspond to a wire grid structure of the wire grid polarizer; preparing a metal ion solution; immersing at least one surface of a carrier substrate in the metal ion solution; and emitting, by an emitter device, an electron beam to the carrier substrate, and controlling a movement of the electron beam according to the pattern data to deposit a metal on the carrier substrate at a position where the electron beam passes, to form the wire grid structure.