A method is for producing an ornamental design (O) in a clearcoat layer (K). The ornamental design (O) is produced by a selective matting of the clearcoat layer (K) by working the clearcoat layer (K) by a laser. The working of the clearcoat layer may be performed by a UV laser. Additionally, the working of the clearcoat layer K may be performed by electromagnetic waves at a wavelength of about 355 nm. Furthermore, the working of the clearcoat layer K may be performed by a laser operating at a frequency of about 23 500 Hz. Still further, the working of the clearcoat layer (K) may be performed by a laser operating with a pulse duration of about 2 s. The working of the clearcoat layer (K) may be performed by a laser operating with a line spacing of about 0.03 mm

The present invention refers to a method for decorating a material comprising the steps of: applying a three-dimensional layer (110) by inkjet printing on at least a part of a support (100). Apply one or more of the following layers on at least a part of the support on which the three-dimensional layer has been created: release layer, texturing layer (120), decorative layer (130), white layer (140), colored layer, functional layer, adhesive layer (150). Apply the transferable decoration on at least part of a material (160) to be decorated. Remove the support (100). Reveal the 3D.

Provided is a matte article that has excellent matte effect visibility and texture as well as an excellent soft touch feeling. A matte article having, on at least a part of a surface thereof, a surface shape with an Spc (arithmetic mean curvature of protrusion vertexes) of more than 4000 mm.sup.?1 as specified in JIS B0601:2013 and an Rsm (average length of curve elements) of less than 30 ?m as specified in JIS B0601:2013.

This disclosure relates to superhydrophobic materials and/or surfaces comprising a shrinkable polymer substrate and at least one polysiloxane layer, wherein the materials and/or surfaces comprise microscale wrinkles and nanoscale features that form hierarchical structures. Methods of making and uses thereof are also disclosed herein.

A system and a method include a substrate wrinkled coating having a substrate, and a curing layer on top of the substrate. The curing layer includes a partially cured portion directly atop the substrate, and a completely cured portion having light-diffusive wrinkles on top of the partially cured portion. Properties of the light-diffusive wrinkles are controlled by one or more curing parameters, and a composition of the partially cured portion is the same as a composition of the completely cured portion.

A method of creating decorative artwork including providing a wall-mountable substrate having a paint-receiving upper surface and a wall-mounting surface opposite the paint-receiving upper surface, applying a first coat of resin to the paint-receiving upper surface, applying a metallic substance to the paint-receiving upper surface, and applying a sealer including a quantity of volatile organic compounds to the paint-receiving upper surface at a velocity sufficient to disperse at least one of the first coat of resin and the metallic substance in a plurality of directions with respect to the paint-receiving upper surface to create at least one decorative marking.

An article having a decorative coating includes a plastic substrate having a front surface, a base hardcoating located over the front surface, one or more intermediate layers located over the hardcoating, a TiN layer located over the one or more intermediate layers, an SiO.sub.2 layer or PECVD HMDSO+O.sub.2 etch layer located over the TiN layer, and a protective hardcoating located over the PECVD HMDSO+O.sub.2 etch layer.

Disclosed are a protective coating layer, and a preparation method and use thereof. The present application provides a protective coating layer, including: a rusty-surface liquid layer, a nano-zinc yellow epoxy primer layer, a nano-epoxy micaceous iron oxide (MIO) intermediate coating layer, and a nano-fluorocarbon top coating layer, where the rusty-surface liquid layer is applied on a metal substrate; the nano-zinc yellow epoxy primer layer is applied on a surface of the rusty-surface liquid layer; the nano-epoxy MIO intermediate coating layer is applied on a surface of the nano-zinc yellow epoxy primer layer; and the nano-fluorocarbon top coating layer is applied on a surface of the nano-epoxy MIO intermediate coating layer. The present application effectively solves the technical problem that the existing protective coating layer with nanoparticles exhibits poor adhesion to a substrate and cannot provide a protective effect for a long time.