315 results about "Silica coating" patented technology

Copper chromite particles can advantageously be used as black particles in electrophoretic media and displays. Preferably, the copper chromite particles are coated with a silica coating and a polymer coating.

An object of the invention is to provide a coated article having a protective member which is improved in light transparency, heat resistance, and weather resistance, and easy to manufacture, as typified by a solar battery module which experience no deterioration of performance during long-term outdoor installation; and to provide a coated article capable of protecting a functional film or device from water vapor and gases for dramatically improve the life of the functional film or device. These objects are achieved by a coated article having as a protective member a silica coating which is obtained by applying a polysilazane-containing coating solution on at least one surface of a resinous substrate having light transparency and heat resistance under atmospheric pressure, followed by steam oxidation and heat treatment.

A coating solution comprising 0.1 to 35% by weight of an inorganic or organic polysilazane having repeating units represented by the general formula below and soluble in a solvent and 0.1 to 10% by weight of catalyst such as 4,4′-trimethylenebis(1-methylpiperidine) based on a pure polysilazane content. By applying the coating solution onto the surface of base materials such as metals, plastics, glass, ceramic, wood, cement, mortar, bricks, etc., a silica coating strongly adhered to the base materials can be formed excellent in corrosion resistance and anti-scratch properties and simultaneously excellent in characteristics such as abrasion resistant, long-lasting anti-fouling properties, wetting properties to water, sealing properties, chemical resistance, oxidation resistance, physical barrier effect, heat resistance, fire resistance and antistatic properties.

Silica coated carbon blacks are disclosed and can be prepared by coating a fine dispersion of carbon black, such as a carbon black having an attached organic group(s). Compositions and articles of manufacture, including elastomeric compositions, containing such carbon black are also disclosed.

An anti-reflection coating comprising a mesoporous silica coating composed of mesoporous silica nano-particles formed on a substrate or a dense coating formed on the substrate, the mesoporous silica coating having a refractive index of more than 1.10 and 1.35 or less.

The invention discloses a graphene-containing insulated radiating composition and preparation and application thereof. The composition comprises the components of silica-coating graphene, insulated heat-conducting filler, a surface treating agent, and a function additive. The preparation method comprises the following steps of: hydrolyzing ethyl silicate on the graphene surface by the sol-gel method to obtain graphene coated with a silica film on the surface; adding the surface treating agent to a mixture of the insulated heat-conducting filler and modified graphene; uniformly agitating; then adding the function additive; and uniformly dispersing to obtain the insulated radiating composition. The composition has the advantages that the graphene is processed by insulating and coating, and the insulated heat-conducting filler and additive of other forms are coordinately added, thus the composition shows high radiating improvement effect in the plastic cement and coating fields; and the composition can be widely applied to a heating element and a radiating facility of various electronic products and electrical equipment, and can greatly improve the radiating effect as well as prolong the service life of devices.

A coating composition is provided comprising a) an aqueous dispersion, having a pH of less than 7.5, of silica nanoparticles having average particle diameters of 40 nanometers or less, b) an alkoxysilane oligomer; c) a silane coupling agent, and d) optionally a metal β-diketone complexing agent. The compositions may be used to prepare coated articles wherein the coating is substantially uniform in thickness, durably adheres to the substrate, and provides hydrophilic and / or antireflection surface properties to the substrate.

The present invention aims to realize a battery having high output voltage, high energy density and excellent charge and discharge cycle characteristics through a constitution different from those of conventional batteries. Specifically, one of the following negative electrode base members is used as a negative electrode base member for lithium ion secondary batteries: a negative electrode base member wherein a metal film is formed on a support having an organic film; such a negative electrode base member wherein the surface layer of the organic film is covered with a metal oxide film; a negative electrode base member wherein a metal film is formed on a support having a composite film formed from a composite film-forming material containing an organic component and an inorganic component; and a negative electrode base member wherein a silica coating is formed, on a support having a photoresist pattern, from a silica film-forming coating liquid and a metal film is formed on the support after removing the photoresist pattern.

The invention provides a coated product which is provided with a basal body coated with a silicon dioxide coating nano-particle layer. The thickness of the coating layer is uniform virtually, perpetually adhered on the basal body and provides the surface nature of dereflection and / or hydrophile for the basal body.

By applying the solution comprising 0.5 to 10 % by weight of an inorganic polysilazane having repeating units represented by the general formula below and soluble in a solvent and a catalyst such as 4,4'-trimethylenebis (1-methylpiperidine) etc. onto the surfaces of the bodies and wheels of automobiles, dentures, tombstones, the interior and exterior of a house, products used with water in toilets, kitchens, washrooms, bathtubs, etc., signboards, signs, plastic products, glass products, etc., a rigid and dense silica coating is formed to confer a long-durable hydrophilic effect and anti-fouling effect on the surfaces. The solvent is properly selected from mineral spirit, paraffin type solvents, aromatic solvents, alicyclic solvents and mixture thereof depending on the article being coated.

The invention discloses a production method of the patterned sapphire substrate for the nitride epitaxial growth, which comprises the following steps: a silica coating is deposited on the sapphire substrate used for the nitride epitaxial growth; a general photetch technology is utilized to prepare a mask of photetch patterns; the photetch patterns are etched on the silica coating by utilizing the doped liquid of hydrofluoric acid, ammonium fluoride and H2O; with the patterned silica coating as a mask, the sapphire substrate are etched by adopting the doped liquid of sulphuric acid and phosphoric acid in a wet manner so that the patterns are etched on the sapphire substrate; a dilute hydrofluoric acid solution is used for wet etching so as to remove the residual silica coating and clean the sapphire substrate, and then the preparation of the patterned sapphire substrate is completed. The production method has the advantages of low cost, preventing the sapphire substrate from being damaged by dry etching, etc. The patterned sapphire substrate can be used for the epitaxial growth of nitrides with low dislocation density and high crystal weight.

Modified and functionalized metallic nanoclusters capable of providing an enhanced Raman signal from an organic Raman-active molecule incorporated therein are provided. For example, modifications include coatings and layers, such as adsorption layers, metal coatings, silica coatings, and organic layers. The nanoclusters are generally referred to as COINs (composite organic inorganic nanoparticles) and are capable of acting as sensitive reporters for analyte detection. A metal that enhances the Raman signal from the organic Raman-active compound is inherent in the nanocluster. A variety of organic Raman-active compounds and mixtures of compounds can be incorporated into the nanocluster.

An article comprising a substrate and an anti-reflection coating, and methods for depositing the coating, are disclosed. The coating comprises (a) a first coating layer having a high refractive index deposited on the substrate; (b) an epoxide-silica coating layer deposited onto the high refractive index coating layer, comprising an inorganic silica component and an organic organo-silicate component, and (c) a silica coating layer consisting essentially of silica, deposited directly onto the epoxide-silica coating layer. The anti-reflection coating optionally comprises a stack of coating layers, between the first high refractive index coating layer and the epoxide-silica coating layer, having alternating a low refractive index and a high refractive index. Individual coating layer compositions, refractive indexes, and thicknesses are carefully controlled such that reflectance is minimized through destructive interference in the visible light wavelength range of 400 to 700 nm. The resulting deposited coating provides excellent mechanical, chemical, and environmental durability.

A method for forming a silica coating on at least a portion of the surface of alkaline earth metal carbonate particulates in aqueous suspension and the silica-coated alkaline earth metal carbonate so produced are claimed. The claimed method consists of allowing soluble silicate ions in the aqueous phase to slowly react with the alkaline earth metal carbonate surface to form silica micro-particulates on the surface. This silica coating confers upon the composition unique properties among which are pronounced thixotropic behavior when incorporated into an aqueous suspension and increased oil absorption when dry. The pigment produced by this method is especially suited for use as a filler in paper.

A low-index silica coating may be made by forming silica sol comprising a silane and / or a colloidal silica. The silica precursor may be deposited on a substrate (e.g., glass substrate) to form a coating layer. The coating layer may then be cured and / or fired using temperature(s) of from about 550 to 700° C. A surface treatment composition comprising an organic material comprising an alkyl chain or a fluoro-alkyl chain and at least one reactive functionality comprising silicon and / or phosphorous may be formed, deposited on the coating layer, then cured and / or fired to form an overcoat layer Preferably, the overcoat layer does not substantially affect the percent transmission or reflection of the low-index silica coating. The low-index silica based coating may be used as an antireflective (AR) film on a front glass substrate of a photovoltaic device (e.g., solar cell) or any other suitable application in certain example instances.

A low-index silica coating may be made by forming silica sol comprising a silane and / or a colloidal silica. The silica precursor may be deposited on a substrate (e.g., glass substrate) to form a coating layer. The coating layer may then be cured and / or fired using temperature(s) of from about 550 to 700° C. A capping layer composition comprising an antifog composition including a siloxane and / or hydrofluororether may be formed, deposited on the coating layer, then cured and / or fired to form a capping layer The capping layer improves the durability of the coating. The low-index silica based coating may be used as an antireflective (AR) film on a front glass substrate of a photovoltaic device (e.g., solar cell) or any other suitable application in certain example instances.

The invention relates to a silicon nitride-lithium niobate heterogeneous integrated waveguide device structure and a preparation method of the same. The silicon nitride-lithium niobate heterogeneous integrated waveguide device structure is characterized in that a silicon nitride waveguide in a silica coating layer and a lithium niobate film on the upper surface of the silicon nitride waveguide areheterogeneously integrated to form a ridge waveguide; a traveling wave electrode is arranged on the upper surface of the lithium niobate film; the silicon nitride waveguide is crossed and coupled with the lithium niobate film on the upper surface of the silicon nitride waveguide, and a high speed electric signal is applied to the traveling wave electrode to control the phase of the light wave passing through the lithium niobate film to realize conversion from amplitude modulation of the loaded electric signal to phase modulation of an optical signal; and three-dimensional vertical integrateddesign is utilized to enable integration of the chip to be more compact, so that the space is saved; at the same time insertion loss of the light waveguide can be reduced; 100G light modulation rate can be realized; high speed modulation of the light wave in the lithium niobate film can be realized and the characteristic of low loss propagation through the silicon nitride waveguide is realized; and light modulation with excellent performance is completed. The manufacturing technology of the silicon nitride-lithium niobate heterogeneous integrated waveguide device structure is compatible with the semiconductor processing technology, is high in the modulation efficiency and low in energy consumption, and has important application prospects in the optical signal processing field and other fields.

A low-index silica coating may be made by forming silica sol including a silane and / or a colloidal silica. The silica precursor may be deposited on a substrate (e.g., glass substrate) to form a coating layer. The coating layer may then be cured and / or fired using temperature(s) of from about 550 to 700° C. A barrier undercoating including a metal oxide, such as, silica, alumina, titania, zirconia, and / or an oxynitride of silica may be deposited between the coating layer and substrate. Preferably, the barrier undercoating does not substantially affect the percent transmission or reflection of the low-index silica coating. The low-index silica based coating may be used as an antireflective (AR) film on a front glass substrate of a photovoltaic device (e.g., solar cell) or any other suitable application in certain example instances.

The invention discloses a method for preparing a high temperature resistant composite separator by a lithium ion battery, and belongs to the field of lithium ion battery separators. The method comprises the following steps: active groups are introduced into the surface of a polyolefin microporous film and a micropore through the surface pretreatment of a substrate film, silica sol is prepared by a sol-gel method, and a silica coating is introduced, and is bonded with the substrate film by a chemical bond. The method is simple in preparation process, low in requirement on equipment, and easy to realize the industrialization; the prepared composite separator has the advantages of high mechanical strength, good air permeability, good high temperature resistance, high ionic conductivity, and good adhesion property of silica coating and polyolefin microporous film, and the silica coating is not easy to fall off, so that the safety performance and the comprehensive property of the separator are improved.

The invention relates to a high energy storage density and efficiency polymer composite film and a preparation method thereof. The composite film is composed of a polyvinylidene fluoride matrix and nanofiber with a core-shell structure in the polyvinylidene fluoride matrix, a core layer of the nanofiber with the core-shell structure is ceramic fiber, and the case layer is a silica coating layer. Compared with prior art, the dielectric constant of the composite film can be adjusted by adjusting the content of ceramic fiber, simultaneously, dielectric loss tangent is less than 5%, breakdown field intensity is greater than 2000kV / cm, and energy storage density is 3-7J / cm<3>. The composite film can reduce interfacial polarization generated at a ceramic-compound interface, can increase the energy storage density of PVDF, can be used for capacitor and large power static energy storage materials, has the advantages of simple and practicable operation, low cost, convenience and rapidity, and enables large scale production.

A low-index silica coating may be made by forming a silica precursor having a radiation curable composition including a radiation curable monomer and / or a photoinitiator, and also including a silica sol comprising a silane and / or a colloidal silica. The silica precursor may be deposited on a substrate (e.g., glass substrate or silicon wafer) to form a coating layer. The coating layer may then be cured via exposure to electromagnetic radiation, such as UV radiation. Then, the cured coating layer may be fired using temperature(s) of from about 550 to 700° C., in forming the low-index silica based coating. The low-index silica based coating may be used as an antireflective (AR) film on a front glass substrate of a photovoltaic device (e.g., solar cell) in certain example instances.

A method of producing a silica coating by forming a silica precursor formulation that is coated on a substrate as a continuous liquid phase. The silica precursor formulation is then cured in an ammoniacal atmosphere to produce a continuous, interconnected, nano-porous silica network.

The invention relates to a monolithic flue gas denitration catalyst with silicon-based ceramic as a carrier and a preparation method thereof, which pertains to the fields of atmospheric pollution treatment technology and pollution-free catalyst materials. The monolithic flue gas denitration catalyst is characterized in that the silicon-based ceramic is taken as a first carrier, active silicon dioxide is taken as a second carrier, a proper amount of one or a plurality of transition metal oxides of Mo, W, Cu, Fe, Zr, La, and the like, is added to CeO2 as the active components. The preparation method adopted is as follows: the silicon-based ceramic is immersed into alumina sol, dried and baked to prepare an active silicon dioxide coating, and then immersed into Ce(NO3)3 solution to prepare an active CeO2 coating. Compared with the prior art, the preparation method of the invention not only improves the mechanical and heat stability of the catalyst carrier, and reduces the load of the active components, but also protects the environment without secondary pollution, enhances the activity of the catalyst, and increases the activity temperature window.

Metallic nanoclusters capable of providing an enhanced Raman signal from an organic Raman-active molecule incorporated therein are provided. The nanoclusters may be further functionalized, for example, with coatings and layers, such as adsorption layers, metal coatings, silica coatings, probes, and organic layers. The nanoclusters are generally referred to as COINs (composite organic inorganic nanoparticles) and are capable of acting as sensitive reporters for analyte detection. A variety of organic Raman-active compounds and mixtures of compounds can be incorporated into the nanocluster.

An optical fiber moisture sensor that can be used to sense moisture present in gas phase in a wide range of concentrations is provided, as well techniques for making the same. The present invention includes a method that utilizes the light scattering phenomenon which occurs in a porous sol-gel silica by coating an optical fiber core with such silica. Thus, a porous sol-gel silica polymer coated on an optical fiber core forms the transducer of an optical fiber moisture sensor according to an embodiment. The resulting optical fiber sensor of the present invention can be used in various applications, including to sense moisture content in indoor / outdoor air, soil, concrete, and low / high temperature gas streams.

The present invention provides a method of fabricating a silicon fin useful in preparing FinFET type semiconductor structures. The method is particularly useful for creating fins with a width and smoothness appropriate for sub-50 nm type gates. The method begins with a silicon fin prepared by lithographic means from an SOI type structure such that the fin is larger in dimension, particularly width, than is desired in the final fin. If desired the silicon fin can include a nitride cap. A conformal diffusion layer, such as of silicon dioxide, is then deposited onto the fin and silicon dioxide substrate. A PECVD deposition using TEOS gas is one method to deposit the diffusion layer. The coated fin is then heated and exposed to oxygen. The oxygen diffuses through the diffusion layer and converts a portion of the silicon material to silicon dioxide. This oxidation continues until a desired amount of silicon material is converted to SiO2 such that the remaining silicon has the desired dimensions. The silicon fin is then exposed through wet etching steps that remove the silicon dioxide coating.

An improved nanoparticle for transfecting cells is provided. The nanoparticle includes a core polyplex and a silica coating on the core polyplex and, optionally, a polymer attached to an outer surface of the silica coating , where the polyplex includes an anionic polymer, a cationic polymer, a cationic polypeptide, and a polynucleotide. Also provided is an improved method of modifying intracellular polynucleotides. The method includes contacting a cell with a nanoparticle that includes a core polyplex and a silica coating on the core polyplex and, optionally, a polymer attached to an outer surface of the silica coating, where the polyplex includes an anionic polymer, a cationic polymer, a cationic polypeptide, and a polynucleotide.