The present invention relates to a method for producing water-insoluble quantum dot patterns on and/or within a substrate. The method comprises a step of depositing a deliquescent salt, quantum dots and an acid or salt thereof onto at least one surface region of a substrate such that the deliquescent salt, the quantum dots and the acid or salt thereof are at least partially contacted to form said at least one water-insoluble pattern.

Methods and devices for controlling pressures in microenvironments between a deposition apparatus and a substrate are provided. Each microenvironment is associated with an aperture of the deposition apparatus which can allow for control of the microenvironment.

Interior trim for vehicles, specifically of the type comprising a sandwich structure, where the electrical conductors are integrated by printing with conductive inks, specifically by screen printing, allowing to make compatible the manufacturing method for the interior trim and the printing method for the electrical conductors, while also facilitating the electrical connections through the edges of the trim of the electrical conductors and the electric devices assembled in the interior trim and ensuring the correct operation of the electrical conductors throughout the useful lifetime of the interior trim. The invention also relates to a method for manufacturing an interior trim for vehicles with electrical conductors.

Ink for producing laser light sources. The ink is used for inkjet printing to produce laser light sources of a certain scale. The ink comprises a luminescent dye, a host material, and a solvent. The use of the ink makes it possible to produce laser light sources through inkjet printing. This provides a novel technical solution for cheap and industrial manufacturing of laser light sources and other related products through inkjet printing.

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.

Systems and methods are presented for a swallowable pH sensor made entirely of edible and digestible materials. A substrate is provided and an electrical circuit pattern is printed on a top surface of the substrate. The electrical circuit pattern includes a plurality of interdigitated electrodes and an antenna portion. The substrate is rolled into a cylindrical form such that the interdigitated electrodes are positioned on an outermost layer of the rolled substrate. The rolling of the substrate also causes the antenna portion of the electrical circuit pattern to form into a coil shape.

A sensing decal (400) for use in the production of a sensor, includes a flexible release layer (401), a conductive ink layer (402) and an adhesive layer (403). The conductive ink layer is printed onto a first surface (404) of the flexible release layer and the adhesive layer is printed onto the conductive ink layer. The first surface includes a substantially non-uniform surface (405) and the conductive ink layer includes at least one patterned element (503-509) providing a predetermined set of electrical properties for formation of a sensor.

Systems of electrical devices with high-resolution components and methods of fabricating the electrical devices using micro-molding processes are described. Small foot print electrical devices can be achieved by fabricating components with highly conductive materials, and with closely spaced components.

A modular production system for processing and/or finishing a print substrate, with a plurality of modular units, is characterized in that the modular units comprise a modular fragrance unit, which is designed to apply a fragrance to the print substrate. Furthermore, a method is disclosed for processing and/or finishing a print substrate. Finally, a modular fragrance unit for processing and/or finishing a print substrate is disclosed.

Provided is a transparent conducting film having a favorable optical property, favorable electrical property, and almost no in-plane resistance anisotropy. A method for producing a transparent conducting film provided with a conducting layer containing a metal nanowire and a binder resin, comprises steps of: preparing a coating liquid containing the metal nanowire and the binder resin, and coating the coating liquid on one main face of a transparent substrate, wherein, in the coating step, a bar-coat printing method is performed using a bar provided with a groove having a pitch (P) and a depth (H) which satisfy a ratio P/H of 5 to 30.