Broadband antireflective coating composition and method
First Claim
1. A process for producing broadband antireflective coatings comprising:
- a. preparing a plurality of solutions of an alkoxide precursor material by reacting an alkoxide or alkoxide mixture with water with or without a catalyst at conditions adapted to produce a series of solutions containing particles of a different size in each solution so that the series of solutions has one solution of a smallest size and one or more solutions each having increasing sizes, wherein the alkoxide is represented by the general formula M(OR)x where M is a metal atom, R is an alkyl group, having from one to five carbon atoms, and x is the valency of the metal atom, and whereby the plurality of solutions are aged or have increased solution pH so as to obtain solutions having different particle size ranges and the alkoxide or alkoxide mixture is selected from the group consisting of the alkoxides of silicon, aluminum, titanium, tantalum, niobium, or zirconium;
b. providing a substrate and depositing and drying one or more layers of a first coating over the substrate from the solution having the smallest particle size;
c. depositing and drying one or more additional coatings each having one or more layers over the coating obtained in step B. from solutions having increasing particle sizes; and
d. thermally treating the plurality of deposited coatings from the above steps to obtain a consolidated antireflective coating with a porous structure, wherein the thermal treatment is below the temperature at which the porous structure of the coating will collapse.
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Abstract
The invention relates to antireflective coatings and to a process for depositing the antireflective coatings on solar collector cover plates, optical elements such as lenses and windows in high-energy visible and near-IR lenses and on other glass or metal or metal-alloy or single crystal surfaces, including the steps of hydrolyzing an alkoxysilane, titanium alkoxide, aluminum alkoxide, tantalum alkoxide, niobium alkoxide, or other alkoxy compounds, or a mixture thereof, depending upon the final coating composition desired; to prepare polymeric solutions of the alkoxy compound/or compounds in which the polymer molecules or macromolecules (i.e. the primary particles) grow with time; depositing layers of coatings from the polymeric solutions by state of the art processes (such as spraying, dipping or spinning method), and drying to form chemically bound microporous gel layers; thermally treating the gel-coating in a manner adapted to remove solvent, excess water and residual organics from the gel coating. Microporous coatings produced by the above procedure will be characterized by graded particles and hence graded porosity across the coating thickness, --larger porosity on the top surface and smaller porosity in the substructure--, and will have gradual transition of refractive index (i.e. graded refractive index) across the coating thickness. Coatings produced by the process of this invention can be used to reduce or eliminate reflection losses from surfaces of transmitting optical elements over a wide spectrum of light waves.
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Citations
13 Claims
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1. A process for producing broadband antireflective coatings comprising:
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a. preparing a plurality of solutions of an alkoxide precursor material by reacting an alkoxide or alkoxide mixture with water with or without a catalyst at conditions adapted to produce a series of solutions containing particles of a different size in each solution so that the series of solutions has one solution of a smallest size and one or more solutions each having increasing sizes, wherein the alkoxide is represented by the general formula M(OR)x where M is a metal atom, R is an alkyl group, having from one to five carbon atoms, and x is the valency of the metal atom, and whereby the plurality of solutions are aged or have increased solution pH so as to obtain solutions having different particle size ranges and the alkoxide or alkoxide mixture is selected from the group consisting of the alkoxides of silicon, aluminum, titanium, tantalum, niobium, or zirconium; b. providing a substrate and depositing and drying one or more layers of a first coating over the substrate from the solution having the smallest particle size; c. depositing and drying one or more additional coatings each having one or more layers over the coating obtained in step B. from solutions having increasing particle sizes; and d. thermally treating the plurality of deposited coatings from the above steps to obtain a consolidated antireflective coating with a porous structure, wherein the thermal treatment is below the temperature at which the porous structure of the coating will collapse. - View Dependent Claims (2, 3, 4, 5, 11, 12, 13)
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6. A process for producing a broadband antireflective coating comprising:
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a. preparing a plurality of coating solutions by the steps of mixing; 1. an alkoxide represented by the general formula M(OR)x where M is a metal atom selected form the group consisting of silicon, aluminum, titanium, tantalum, niobium, zirconium and a mixture thereof, where R is an alkyl group having from one to five carbon atoms and x is the valency of the metal atom; 2. water, H2 O; 3. an organic solvent selected form the group consisting of alcohols;
R1 -OH, and ketones ##STR3## or mixtures thereof, where R1 is an alkyl group having from one to five carbon atoms and R2 and R3 are alkyl groups having from one to two carbon atoms, whereby the plurality of solutions in step a. are aged or have increased solution pH so as to obtain solutions having different particle size ranges;b. providing a substitute adapted for coating by the prepared solutions; c. depositing and drying one or more layers of the solution having the smallest particle size onto the substrate to form a gel coating; d. depositing and drying one or more gel coatings each having one or more layers over the gel coating of step c.; and e. thermally treating the deposited coatings to obtain a consolidated antireflective coating with a porous structure, wherein the thermal treatment is below the temperature at which the porous structure of the coating will collapse. - View Dependent Claims (7, 8, 9, 10)
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Specification