Abstract: A compound represented by one of the formulae: BaaMobOc??(1), MOdPeOf??(2) or BagMohPiOj??(3) wherein for formula (1) the ratio of a:b is from 1:100 to 100:1, wherein for formula (2) the ratio of d:e is from 1:100 to less than 1:1 or from greater than 1:1 to 100:1, wherein for formula (3) the ratio of g:h is from 1:100 to less than 1.5:1, wherein for formula (3) the ratio of g:i is from 1:100 to 100:1, wherein for formula (3) the ratio of h:i is from 1:100 to less than 1:2, or from greater than 1:2 to less than 2:1, or from greater than 2:1 to 100:1, and wherein the molybdenum present within the compound is in the 5+ oxidation state.

Abstract: A compound represented by one of the formulae: BaaMobOc??(1), MOdPeOf??(2) or BagMohPiOj??(3) wherein for formula (1) the ratio of a:b is greater than 1:1, wherein for formula (2) the ratio of d:e is from 1:100 to 0.45:1 or from 0.55:1 to 100:1, wherein for formula (3) the ratio of g:h is from 1:7 to 1:2 and the ratio of g:i is from 1:3 to 1:1, or the ratio of g:h is from 0.6:1 to 100:1 and the ratio of g:i is from 2.2:1 to 100:1, and wherein the molybdenum present within the compound is in the 4+ oxidation state.

Abstract: A method of making a doped titanium oxide coating in a float glass manufacturing process and the coated glass article made thereby wherein the dopant is a niobium or tantalum compound. The doped titanium oxide coating preferably exhibits an electrical conductivity>1×10?3 S/cm.

Abstract: A method of making a doped titanium oxide coating in a float glass manufacturing process and the coated glass article made thereby wherein the dopant is a niobium or tantalum compound. The doped titanium oxide coating preferably exhibits an electrical conductivity>1×10?3 S/cm.

Abstract: The invention relates to an apparatus for depositing thin film coatings on a substrate. The deposition apparatus is designed to keep gaseous reactant materials to be deposited apart from one another in the deposition apparatus, by one or more separation devices and/or methods, but nevertheless, to allow the chemical reactants to mix and react at or near the substrate surface, rapidly enough to create a uniform film at commercially viable deposition rates.

Abstract: A method of depositing an electrically conductive titanium oxide coating on a glass substrate, preferably by atmospheric chemical vapor deposition in a float glass manufacturing process, utilizes a precursor gas mixture including a halogenated, inorganic titanium compound, an organic oxygen containing compound, a reducing gas and one or more inert carrier gases.

Abstract: A method of making a doped titanium oxide coating in a float glass manufacturing process and the coated glass article made thereby wherein the dopant is a niobium or tantalum compound. The doped titanium oxide coating preferably exhibits an electrical conductivity >1×10?3 S/cm.

Abstract: The invention relates to an apparatus for depositing thin film coatings on a substrate. The deposition apparatus is designed to keep gaseous reactant materials to be deposited apart from one another in the deposition apparatus, by one or more separation devices and/or methods, but nevertheless, to allow the chemical reactants to mix and react at or near the substrate surface, rapidly enough to create a uniform film at commercially viable deposition rates.

Abstract: A multi-layer thin film having as a primary component, a coating of highly doped zinc oxide, and optionally, a color suppression underlayer and a protective metal oxide overcoat. The film stack is preferably deposited on a transparent substrate by atmospheric chemical vapor deposition. The film stack exhibits a desirable combination of properties including high visible light transmittance, relatively low solar energy transmittance, low emissivity, and high solar selectivity.

Abstract: A method of depositing an electrically conductive titanium oxide coating on a glass substrate, preferably by atmospheric chemical vapor deposition in a float glass manufacturing process, utilizes a precursor gas mixture including a halogenated, inorganic titanium compound, an organic oxygen containing compound, a reducing gas and one or more inert carrier gases.

Abstract: A laminated glass unit having at least two sheets of glass separated and bonded by a polymeric interlayer material, and further having multi-layer thin film coatings on each of the unbonded surfaces of the at least two glass sheets, is disclosed. Two or more of such laminated glass units can be utilized in various configurations to form an insulated glass unit. The thin films deposited on the unbonded glass surfaces have anti-reflective, iridescence-suppressing and solar control properties when suitable configurations, materials and layer thicknesses are chosen. The laminated glass unit and insulated glass units of the invention exhibit an excellent combination of low visible light reflectance and thermal insulating properties.

Abstract: A multi-layer, low-emissivity, solar control article comprises a dielectric substrate, a first dielectric metal oxide layer deposited on the substrate, a first highly conductive, silver-free metal oxide layer deposited on the first dielectric metal oxide, and a second dielectric metal oxide deposited on the first highly conductive, silver-free metal oxide layer. The aforementioned coating layer sequence may be repeated as necessary to achieve the desired properties. An iridescence suppressing interlayer may, optionally, be utilized in connection with the low-emissivity, solar control coating.

Abstract: A process for the production of a zinc oxide coating on a moving glass substrate provides a precursor mixture of a dialkylzinc compound, an oxygen-containing compound and an inert carrier gas. The precursor mixture is directed along a surface of the glass substrate in an atmospheric pressure, on-line, chemical vapor deposition process. The precursor mixture is reacted at the surface of the glass substrate to form a zinc oxide coating, essentially devoid of nitrogen, at a growth rate of >100 ?/second.

Abstract: A method of forming zinc oxide films on a heated, moving glass substrate utilizes a gaseous precursor mixture comprising an alkyl zinc compound chelated by at least one tridentate ligand, an oxygen-containing compound, and one or more inert carrier gases.

Abstract: An atmospheric chemical vapor deposition process for laying down a magnesium oxide coating on a moving glass substrate through the reaction of an organic ester and an organomagnesium compound. The resulting article has a magnesium oxide coating which can be of substantial thickness because of the high deposition rates attainable with the novel process. Preferably, the coating deposition rates resulting from the method of the present invention may be greater than or equal to 15 ? per second.

Abstract: A multi-layer, low-emissivity, solar control article comprises a dielectric substrate, a first dielectric metal oxide layer deposited on the substrate, a first highly conductive, silver-free metal oxide layer deposited on the first dielectric metal oxide, and a second dielectric metal oxide deposited on the first highly conductive, silver-free metal oxide layer. The aforementioned coating layer sequence may be repeated as necessary to achieve the desired properties. An iridescence suppressing interlayer may, optionally, be utilized in connection with the low-emissivity, solar control coating.

Abstract: A multi-layer thin film having as a primary component, a coating of highly doped zinc oxide, and optionally, a color suppression underlayer and a protective metal oxide overcoat. The film stack is preferably deposited on a transparent substrate by atmospheric chemical vapor deposition. The film stack exhibits a desirable combination of properties including high visible light transmittance, relatively low solar energy transmittance, low emissivity, and high solar selectivity.

Abstract: A process for the production of a zinc oxide coating on a moving glass substrate provides a precursor mixture of a dialkylzinc compound, an oxygen-containing compound and an inert carrier gas. The precursor mixture is directed along a surface of the glass substrate in an atmospheric pressure, on-line, chemical vapor deposition process. The precursor mixture is reacted at the surface of the glass substrate to form a zinc oxide coating, essentially devoid of nitrogen, at a growth rate of >100 ?/second.

Abstract: A method of forming zinc oxide films on a heated, moving glass substrate utilizes a gaseous precursor mixture comprising an alkyl zinc compound chelated by at least one tridentate ligand, an oxygen-containing compound, and one or more inert carrier gases.

Abstract: A multi-layer, low-emissivity, solar control article comprises a dielectric substrate, a first dielectric metal oxide layer deposited on the substrate, a first highly conductive, silver-free metal oxide layer deposited on the first dielectric metal oxide, and a second dielectric metal oxide deposited on the first highly conductive, silver-free metal oxide layer. The aforementioned coating layer sequence may be repeated as necessary to achieve the desired properties. An iridescence suppressing interlayer may, optionally, be utilized in connection with the low-emissivity, solar control coating.