An antifouling structure of the present invention is produced by impregnating a base having a porous structure layer including micropores with a non-volatile liquid.

A relationship between an average opening diameter of the micropores and the number of the micropores per unit area of the porous structure layer satisfies the following formula (1). The non-volatile liquid retained in the porous structure layer can be sufficiently utilized, and antifouling property can be exhibited for a long time.

Average Opening Diameter (nm)Number of Micropores/100 (nm.sup.2)>0.6 nm.sup.1 Formula (1)

The present invention provides scalable, solution based processes for manufacturing electrochromic materials comprising metal oxide films for use in electrochromic devices. The electrochromic material comprises a transparent conductive substrate coated with an electrochromic metal oxide film, wherein the metal oxide film is formed by a process comprising the steps of: a) providing the conductive substrate; b) coating the substrate with a solution of one or more metal precursors; and c) exposing the coated substrate to near-infrared radiation, UV radiation and/or ozone in an aerobic atmosphere. The present invention also provides electrochromic devices incorporating these electrochromic materials.

A heat-ray-reflective, light-transmissive base material is provided that includes a light-transmissive base material; a hard-coat layer disposed over one surface of the light-transmissive base material; and a transparent conductive oxide layer containing a transparent conductive oxide, disposed over the hard-coat layer.

The present invention provides a conductive laminate for a touch panel which includes a substrate, and a patterned metal layer which is visually recognized to have greater blackness when viewed from the substrate side; a touch panel; and a transparent conductive laminate. The conductive laminate includes a substrate which has two main surfaces; a patterned plated layer which is disposed on at least one main surface of the substrate and has a functional group that interacts with metal ions; and a patterned metal layer which is disposed on the patterned plated layer, in which the patterned plated layer includes a metal component constituting the patterned metal layer and the ratio of the average peak intensity resulting from the metal component contained in the patterned plated layer to the average peak intensity resulting from the metal component constituting the patterned metal layer is in a range of 0.5 to 0.95.

A method of coating a superstrate using a vacuum chuck containing ridges can comprise attaching the superstrate on the vacuum chuck; applying on the superstrate a liquid layer of a coating composition, the coating composition comprising a coating agent and a non-fluorinated solvent, wherein the non-fluorinated solvent has a boiling point of at least 165 C.; and solidifying the coating composition to form a solid coating layer. The material of the superstrate can have a thermal conductivity of not greater than 10 W/mK and the solid coating layer obtained after solidifying may comprise a smoothness value (SM) of not greater than 1%, the smoothness value being defined as SM=(C.sub.RD/C.sub.T)100%, with C.sub.RD being a maximum roughness depth of the coating layer and C.sub.T an average thickness of the coating layer over a length of 10 mm of the solid coating layer.

Provided are a member that reduces a change in refractive index at high humidity (60% RH or more and less than 90% RH) and a method of manufacturing the member. The member comprises a base material and a porous layer formed on at least any one of surfaces of the base material, wherein the porous layer has dN.sub.2 of 5 nm or more and 20 nm or less and dH.sub.2O of 25 nm or more and 75 nm or less, and has a contact angle with respect to water of less than 60, in which dN.sub.2 is defined as a diameter of a pore at a time when a differential pore volume becomes maximum in the differential pore distribution in nitrogen adsorption and dH.sub.2O is defined as a diameter of a pore at a time when a differential pore volume becomes maximum in the differential pore distribution in water vapor adsorption.

Solvents for macromolecules generally believed to be insoluble in their pristine form are identified by generation of a solvent resonance in the relationship between solvent quality (deduced by Rayleigh scattering) and an intrinsic property of solvents. A local extreme of the solvent resonance identifies the ideal intrinsic property of an ideal solvent which may then be used to select a particular solvent or solvent combination. A solvent for graphene is used in the production of transparent conductive electrodes.

A method for preparation of a self-cleaning coating solution is provided. The method comprises mixing an aluminium compound with a solution of an ethanol compound to form a solution. Further, the formed solution is subjected to a first magnetic stirring. After the first magnetic stirring a first transparent solution is formed. Further, a stabilizing agent is added to the first transparent solution of the aluminium compound and the ethanol compound. Subsequent to adding the stabilizing agent a translucent solution is formed. Finally, the formed translucent solution is subjected to a second magnetic stirring for forming a homogeneous second transparent solution. The formed second transparent solution is a coating solution.

An article including a glass or glass ceramic substrate, a noble metal layer, an adhesion promoting layer positioned between and bonded to the substrate and the noble metal layer, and a conductive metal layer positioned on and bonded to the noble metal layer. The adhesion promoting layer includes a siloxy group bonded with the substrate and a thiol group bonded to the noble metal layer. A method for manufacturing an article including applying an adhesion promoting layer comprising mercaptosilane to at least a portion of a glass or glass ceramic substrate, wherein siloxane bonds are formed between the mercaptosilane and the substrate, applying a noble metal layer to the adhesion promoting layer, the noble metal layer bonds with a thiol present in the mercaptosilane, thermally treating the noble metal layer, and applying a conductive metal layer to the noble metal layer.

A laminate includes: a near infrared light absorbing layer that includes a near infrared absorbing colorant; and a color filter layer that is arranged adjacent to the near infrared light absorbing layer in a thickness direction and includes a chromatic colorant, in which in at least one of the near infrared light absorbing layer or the color filter layer, a content of a compound in which an acid group selected from a sulfo group, a phosphate group, or a carboxyl group is bonded to a colorant skeleton is 0.1 to 99.9 mass % with respect to a total mass of compounds having a colorant skeleton.