To provide a liquid composition capable of forming a coating film which has sufficient ultraviolet-absorbing ability and infrared-absorbing ability. A liquid composition for forming a coating film comprising an infrared absorber selected from indium tin oxide, antinomy tin oxide and a composite tungsten oxide, an ultraviolet absorber selected from a benzophenone compound, a triazine compound and a benzotriazole compound, a dispersing agent having an acid value and/or an amine value, a binder component and a liquid medium, wherein the dispersing agent is contained in a content such that the product of the sum (mgKOH/g) of the acid value and the amine value of the dispersing agent, and the mass ratio of the dispersing agent to the infrared absorber, is from 2 to 30 (mgKOH/g).

This coated steel sheet comprises: a steel sheet; a primer coating film that is arranged on the steel sheet and contains a chromic acid-based rust preventive pigment and aggregate that serves as primary particles, while not containing porous particles; and a top coating film that is arranged on the primer coating film. The aggregate satisfies the following formula (1) and formula (2).

D.sub.10≧0.6T (1)

D.sub.90<2.0T (2)

(In the formulae, D.sub.10 represents the 10% particle diameter (μm) of the aggregate in the number-based cumulative particle size distribution; D.sub.90 represents the 90% particle diameter (μm) of the aggregate in the number-based cumulative particle size distribution; and T represents the film thickness (μm) of a portion of the primer coating film, in which the aggregate is not present.)

Provided herein are metal nanoclusters, having a high absorption to volume ratio, and uses of the same, such as in generating singlet oxygen, or in protecting surfaces from high intensity light.

Disclosed are an environment-friendly heat shielding film using a non-radioactive stable isotope and a manufacturing method therefor and, more specifically, an environment-friendly heat shielding film using a non-radioactive stable isotope and a manufacturing method therefor, wherein a heat shielding layer is formed on one surface of a substrate layer; the heat shielding layer is composed of stable isotopes as elements constituting a precursor and contains a non-radioactive stable isotope tungsten bronze compound having an oxygen-deficient .sup.(Y)A.sub.x.sup.(182,183,184,186)W.sub.1O.sub.(3-n) type hexagonal structure, thereby preventing the generation of radioactive materials, fundamentally blocking haze, and improving the visible light transmittance and the infrared light blocking rate; and the heat resistance and durability problems that may occur when the heat shielding layer is formed of the non-radioactive stable isotope tungsten bronze compound are solved by a passivation film.

Corrosion inhibition systems, including coated substrates, coating materials and corrosion inhibition compounds, and methods of making the same are disclosed. These systems and methods include corrosion inhibition compounds that are responsive to corrosion at a surface, releasing active inhibitor groups upon a corrosion stimulus. The active inhibitor groups are selected to block corrosion at the surface by inhibiting oxidation reactions, reduction reactions and/or by forming a passivation layer.

A corrosion inhibiting composition includes a first plurality of carriers and a second plurality of carriers. The first plurality of carriers has a first carrier body which encapsulates a film-forming compound. The second plurality of carriers has a second carrier body encapsulates a corrosion inhibitor. Each of the first and second carrier bodies is formed of a degradable material. Coatings and methods for inhibiting corrosion on a metal substrate are also described herein.

A composition is provided comprising a high viscosity amino functional silicone fluid, a silicone glycol copolymer, an aqueous-based intumescent flame retardant, and an aqueous-based concentrated cationic fluoropolymer system that cures at ambient temperatures. The composition is characterized by providing a protective coating and enhancing the appearance of a wide variety of porous and non-porous vehicle interior material surfaces, including rubber, vinyl, fabric, carpeting, metal, metal alloys, chrome, leather, carbon fiber, aluminum, different grains of wood, dashboard tech screens, plastic made from renewable sources, and plastic made from non-renewable sources.

A composition is provided comprising a high viscosity amino functional silicone fluid, a silicone glycol copolymer, an aqueous-based intumescent flame retardant, and an aqueous-based concentrated cationic fluoropolymer system that cures at ambient temperatures. The composition is characterized by providing a protective coating and enhancing the appearance of a wide variety of porous and non-porous vehicle interior material surfaces, including rubber, vinyl, fabric, carpeting, metal, metal alloys, chrome, leather, carbon fiber, aluminum, different grains of wood, dashboard tech screens, plastic made from renewable sources, and plastic made from non-renewable sources.

An ultraviolet light absorber (UVA) Universal Composition powder coating is provided. The composition can include about 73.0 to about 78.0 weight percent (wt. %) of a silicone resin, about 2.0 to about 7.0 wt. % of a hardener, about 0.7 to about 1.2 wt. % of a UV stabilizer, about 0.7 to about 1.2 wt. % of a flow modifier, about 15.0 to about 20.0 wt. % of a glass flake, and about 0.1 to about 0.6 wt. % of a catalyst. A UVA additive composition including a plurality of UVA additive particles having a continuous phase of a silicon resin that contains a hardener, a UV stabilizer, a flow modifier, glass flakes, and a catalyst, wherein the plurality of UVA additive particles have a particle size of 0.5 to 100 μm, is also provided.

Disclosed is a radiation curable coating composition, including polymerizable, unsaturated compounds such as (meth)acrylates, vinyl compounds, or the like in a concentration range of 15-98% by weight, with an addition of 5-35% by weight, preferably 5-20% by weight, of organic UV absorber(s), wherein the UV absorber(s) has/have its/their maximum absorption coefficient in a wavelength range of <390 nm, preferably <350 nm, wherein the coating composition optionally includes other components in the amount of the balance to 100% by weight, and a method for curing such a coating composition. Also disclosed is a coating composition of this kind, wherein the organic UV absorber is radically polymerizable.