An apparatus including a first device which moves a first portion of a soft, damp, slightly pressed slab out of alignment with a majority of the slab and thus introduces a first crack in the slab; and a device for spraying a first colored material into the first crack of the slab. The first device which moves the first portion of the slab out of alignment with the rest of the slab may include a first cylinder. The device for spraying the first colored material in the first crack of the slab may include a robotic apparatus. In at least one embodiment, the apparatus may also include a second device which moves a second portion of the slab out of alignment with the majority of the slab and thereby introduces a second crack in the slab.

A component for use in a semiconductor processing chamber is provided. A component body comprises a metallic material or ceramic material. A coating is disposed on a surface of the component body where the coating comprises a layer of yttrium aluminum oxide, the yttrium aluminum oxide layer being formed of a composition having a molar ratio of 1.0-0.9 yttrium to 1.0-1.1 aluminum over at least 90% of the yttrium aluminum oxide layer.

A passivated perovskite film is provided, the passivated perovskite film comprising: a perovskite film, which includes an upper surface and at least one grain boundary; and a biphenyl methyl ammonium halide coating on the upper surface of the perovskite film, wherein the halide is selected from the group consisting of chloride, bromide and iodide.

A method of forming a directed self-assembled (DSA) layer on a substrate by: providing a substrate; applying a layer comprising a self-assembly material on the substrate; and annealing of the self-assembly material of the layer to form a directed self-assembled layer by providing a controlled temperature and gas environment around the substrate. The controlled gas environment comprises molecules comprising an oxygen element with a partial pressure between 10-2000 Pa.

A method of forming a coating can include: preparing a substrate surface with adherent characteristics; and/or applying at least one non-carbon-based topological insulator to the substrate surface to provide a topological insulator layer on the substrate surface. The at least one non-carbon-based topological insulator can have one or more of selected optical transmittance, selected thermal conductivity, selected electrical conductivity, or selected electrical resistivity.

The present invention is directed to a water borne coating composition. The composition according to the present invention comprises an emulsified binder, wherein the binder is a polymer selected from the group consisting of polymers prepared by emulsion polymerization of unsaturated vinyl, acrylate and/or methacrylate monomers, alkyd, polyurethane, and epoxy, 0.3% to 10% by weight of a second polymer selected from one or more of the group consisting of poly(vinyl alcohol) and water-soluble copolymers having repeat units of vinyl alcohol, wherein, if the second polymer is poly(vinyl alcohol), at least 85 wt % of the second polymer has a number of repeat units not less than 2,000, and 0% to 15% by weight of a cellulose-based filler, based on the total weight of the composition, wherein the weight ratio of second polymer to binder is in the range of from 1:100 to 1:1. The composition maybe used in various applications to form a decorative coating which has special visual and tactile effect.

A coating, in particular a coating for a back side of a brake pad opposite a braking side, includes a pair of bonding layers and a composite layer. Each of the bonding layers includes an epoxy material. The composite layer is disposed between the pair of bonding layers, and includes a mixture of a rubber material and particles of a secondary material. A method for forming the coating includes coating a layer of epoxy onto the surface to be coated to form a first bonding layer, coating the mixture of the rubber material and particles of a secondary material onto the first bonding layer to form a composite layer, coating a layer of epoxy to the composite layer to form a second bonding layer, and then curing the coating via a curing process.

The process for the manufacturing of a supporting surface for furnishing accessories, in particular for tables and tops for kitchens and/or bathrooms, comprises the phases of: I providing a raw slab (2) made of raw ceramic material; II firing the raw slab (2) to obtain a fired slab (5); III modeling the fired slab (5) to obtain a shaped slab (6) comprising an exposed surface (8) and a lateral surface (9) transverse to the exposed surface (8); IV decorating the shaped slab (6) with ceramic pigments (12) to obtain a decorated slab (13) which is decorated on said lateral surface (9); V firing the decorated slab (13) and the ceramic pigments (12) to obtain a supporting surface (1) for furnishing accessories.

Methods of protecting a submerged surface include applying an adhesion-promoting layer onto a surface. An inner polymer layer is applied onto the adhesion-promoting layer. The inner polymer layer is impregnated with a biologically active chemical substance that inhibits biofouling-induced chemical, biological, and bio-proliferative damage. An outer polymer layer is applied onto the inner polymer layer. The outer polymer layer is impregnated with a biologically active chemical substance that inhibits biofouling-induced chemical, biological, and bio-proliferative damage and that repels biofouling organisms to prevent invasion of the inner polymer layer.

Apparatuses and methods for forming a film on a substrate are described. The film is formed on the substrate by depositing an adamantane monomer and an initiator on the substrate to form a polymerizable seed layer and curing the polymerizable seed layer to form a polyadamantane layer.