A coating method for producing a function layer on mechanically loaded components or surfaces includes providing or applying a first material layer of a first material or substrate matrix having a mechanical flexibility higher than that of a second material on a substrate constituting the component or the surface, respectively, structuring the first material layer such that the material layer surface of the first material layer, which is opposite to the substrate, obtains a three-dimensionally molded basic structure with projections and recesses, and coating the material layer surface of the first material layer with a second material layer of the second material in such a way that the second material layer adopts substantially the basic structure of the material layer surface with the projections and recesses. Also, surface layer structures can be produced by this method.

Structures and methods for forming a patterned graphene layer on a substrate. One such method includes forming at least one patterned structure of a carbide-forming metal or metal-containing alloy on a substrate, applying a layer of graphene on top of the at least one patterned structure of a carbide-forming metal or metal-containing alloy on the substrate, heating the layer of graphene on top of the at least one patterned structure of a carbide-forming metal or metal-containing alloy in an environment to remove graphene regions proximate to the at least one patterned structure of a carbide-forming metal or metal-containing alloy, and removing the at least one patterned structure of a carbide-forming metal or metal-containing alloy to produce a patterned graphene layer on the substrate, wherein the patterned graphene layer on the substrate provides carrier mobility for electronic devices.

An article may include a substrate comprising a matrix material and a reinforcement material, a layer formed on the substrate, an array of features formed on the layer, and a coating formed on the layer and the array of features. The article may have improved thermal and/or mechanical stress tolerance compared to an article not including the array of features formed on the layer.

An embossing tool comprised of a pressing plate or endless belt that includes a structured surface, a first gloss level over the full area of the structured surface, and further, different gloss levels in several selected areas of the structured surface. The gloss levels are created by mechanical post-treatment and/or chemical post-treatment. A method for producing the embossing tool is also involved. The structured surface is provided with a first gloss level over the full area and receives further, different gloss levels in several selected areas in further work steps. The gloss levels are created via a mechanical post-treatment and/or chemical post-treatment.

A grain-oriented electrical steel sheet has low iron loss properties obtained though magnetic domain refining treatment by a chemical means. The steel sheet has a linear groove extending in a direction forming an angle of 45 or less with a direction orthogonal to a rolling direction of the steel sheet, in which presence frequency of fine grains with a length in the rolling direction of 1 mm or less in a floor portion of the groove is 10% or less, including 0% indicative of the absence of fine grains, the groove is provided with a forsterite film in an amount of 0.6 g/m.sup.2 or more in terms of Mg coating amount per one surface of the steel sheet, and an average of angles ( angles) formed by <100> axes of secondary recrystallized grains facing the rolling direction and a rolling plane of the steel sheet is 3 or less.

An apparatus and method for forming a patterned graphene layer on a substrate. One such method includes forming at least one patterned structure on a substrate; applying a layer of graphene on top of the at least one patterned structure on the substrate; heating the layer of graphene on top of the at least one patterned structure to remove one or more graphene regions proximate to the at least one patterned structure; and removing the at least one patterned structure to produce a patterned graphene layer on the substrate, wherein the patterned graphene layer on the substrate provides carrier mobility for electronic devices.

The invention relates to a method for producing a visible covering (1) comprising the following steps: mixing a stabilising agent with a granular material (2), introducing the granular material (2) into a receiver (3) to form a moulded article (4), connecting of at least a surface layer (9) of the moulded article with a carrier layer (10), removing the composite of surface layer (9) and carrier layer (10), wherein the visible covering (1) is obtained. The invention further related to a visible covering (1) produced with the method according to the invention and the use thereof as a facing of ceilings, walls, floors, doors, roofs and/or tabletops.

A metallic decorative part for a vehicle display device includes a substrate body molded from a synthetic resin, a metal thin film that is formed of metal and deposited on a surface of the substrate body, and a plurality of grooves deposited on a surface of the metal thin film in accordance with a shape of the surface of the substrate body. The grooves are formed so that a width is larger than 0 and equal to or smaller than 3.0 m, and a height is larger than 0 and equal to or smaller than 1.0 m. Accordingly, the metallic decorative part for a vehicle display device can properly secure a metallic texture recognized by a viewer with a configuration in which the metal thin film is deposited on the surface of the substrate body made of resin.

An article may include a substrate defining a surface imperfection and a coating deposited over the substrate. The coating does not substantially reproduce the surface imperfection, and the coating comprises mullite and at least one rare earth silicate, rare earth oxide, alumina, boron oxide, alkali metal oxide, alkali earth metal oxide, silicon, barium strontium aluminosilicate, barium aluminosilicate, strontium aluminosilicate, calcium aluminosilicate, magnesium aluminosilicate, or lithium aluminosilicate. In some examples, the coating may be a first coating deposited from a slurry over the substrate, and a second coating may be deposited over the first coating. In other examples, a first coating that substantially reproduces the surface imperfection may be deposited over the substrate, and the coating that does not substantially reproduce the surface imperfection may be deposited over the first coating.

Homogeneous and transparent protective coatings for precious metals and copper alloys and techniques for forming the coatings on precious metals and copper alloys are provided. In an embodiment, ionic oxide film is deposited onto a surface of a substrate including a metal, such as a precious metal and/or a copper alloy, using pulsed chemical vapor deposition (PCVD). A homogenous and transparent solid film based on ionic oxide is formed on the surface of the substrate in response to the depositing.