Abstract: An object is to provide a method of making a metal oxide film with a sufficiently high degree of crystal orientation, without difficulties, at low cost, and with little damage to a base material and the metal oxide film, and to provide laminates and electronic devices using the same. A method includes a step of forming a metal film having a (111) plane, on a base material; a step of forming a metal oxide film on the (111) plane of the metal film; and a step of maintaining a temperature of the metal oxide film formed on the (111) plane of the metal film, at 25-600° C. and irradiating the metal oxide film with UV light.

Abstract: The invention relates to a photosensitive element comprising a support film and a photosensitive layer derived from a photosensitive resin composition formed on the support film, wherein the support film haze is 0.01-1.5%, the total number of particles with diameters of 5 ?m and larger and aggregates with diameters of 5 ?m or larger in the support film is no greater than 5/mm2, the photosensitive layer contains a binder polymer, a photopolymerizable compound with an ethylenically unsaturated bond and a photopolymerization initiator, and the thickness T of the photosensitive layer and the absorbance A of the photosensitive layer at 365 nm satisfies the relationship represented by inequality (I): 0.001?A/T?0.020??(I).

Abstract: An optical component includes a substrate and a fluorine-doped thin film formed on the substrate. This fluorine-doped thin film is dense, and thus very low absorbing and insensitive to various vacuum, temperature, and humidity conditions. This dense film has a high refractive index, which remains stable irrespective of environmental conditions. The fluorine-doped thin film can advantageously ensure low scattering, low reflectance, and high transmittance. Moreover, the fluorine-doped thin film is damage resistant to incident radiation density. The fluorine-doped thin film may be a fluorine-doped silicon oxide film having a thickness of approximately 1-10 nm and a fluorine concentration of 0.1% to 5%.

Abstract: The present invention is directed to substrates comprising amplified patterns, methods for making the amplified patterns, and methods of using the amplified patterns to form surface features on the substrates.

Abstract: A decoration film, a method of fabricating a decoration film, and a method of fabricating a decoration device are provided. The decoration film includes a substrate and a relief pattern layer disposed on the substrate. The relief pattern layer has a relief surface away from the substrate and includes a decoration relief portion and a marker relief portion located around the decoration relief portion, wherein the relief pattern layer is remained on the substrate after the decoration process.

Abstract: The present invention relates to a diblock copolymer that may facilitate formation of a finer nano pattern, and be used for manufacture of an electronic device including a nano pattern or a bio sensor, and the like, a method for preparing the same, and a method for forming a nano pattern using the same, The diblock copolymer comprises a hard segment including at least one specific acrylamide-based repeat unit, and a soft segment including at least one (meth)acrylate-based repeat unit.

Abstract: A textured heat transfer label includes a textured portion formed from a highly cross-linked UV ink and a thermoplastic background ink.

Abstract: Techniques or processes for providing markings on products are disclosed. The markings provided on products can be textual and/or graphic. The techniques or processes can provide high resolution markings on surfaces that are flat or curved. In one embodiment, the products have housings and the markings are to be provided on the housings. For example, the housing for a particular product can include an outer housing surface and the markings can be provided on the outer housing surface. The markings can be formed using a ultra-violet (UV) curable material that can be selectively cured on a surface (e.g., housing surface) in places where markings, namely text and/or graphics, are to be provided.

Abstract: A method for coating a work piece with resin including applying a controlled volume of liquid resin to the work piece with an applicator and allowing consecutive streams of resin to meld together to form a self leveling surface. The resin can be actively or passively cured. The work piece can be planar or cylindrical.

Abstract: The present invention is directed to a method of sealing the free end of a hollow fiber membrane for use in a single header filtration module by dipping the end of the membrane into a low-viscosity light-curable adhesive and curing the adhesive. The invention further encompasses the resulting sealed hollow fiber membrane with a diameter that is only slightly larger than the diameter of the unsealed membrane.

Abstract: The invention relates to a component (30) for a filter unit for filtering fluids, in particular hydraulic fluids, comprising at least in areas an insertion or application of magnetisable and/or magnetised particles, whereby, using a simplified design, a magnetic separation of contaminants in a fluid flowing through a filter unit is achieved. The component can be in the form of a film (30) and can be an externally or circumferentially arranged support means for a filter element (10). In the manufacture of the component (30), said component is provided at least in areas with an insertion and/or application of magnetisable and/or magnetised particles.

Abstract: A method for repairing process-related damage of a dielectric film formed on a substrate caused by processing the dielectric film includes: irradiating the damaged dielectric film with UV light in an atmosphere of hydrocarbon-containing gas to restore the surface of the dielectric film; and irradiating the surface-restored dielectric film with UV light in an atmosphere of oxygen gas to partially remove the hydrocarbon film.

Abstract: According to one embodiment, a lens array of this embodiment is equipped with a plurality of lenses formed on a substrate, and light-blocking films including a plurality of layers, are formed by using an ultraviolet curable ink deposited between the lenses.

Abstract: A method of preparing an organic light-emitting device includes forming an organic emission unit on a substrate, and forming a thin film encapsulation layer that contacts an environmental element, and that includes at least one inorganic layer including a low temperature viscosity transition (LVT) inorganic material, wherein the inorganic layer is formed using a process including forming a pre-inorganic layer including the LVT inorganic material by providing the LVT inorganic material onto the organic emission unit on which the environmental element is located, performing a first healing process on the pre-inorganic layer at a temperature greater than a viscosity transition temperature of the LVT inorganic material, and performing a second healing process on the pre-inorganic layer having undergone the first healing process to increase a binding force between the environmental element and the LVT inorganic material, and to increase a binding force among the LVT inorganic material.

Abstract: According to one embodiment, a lens array includes a substrate with a lens surface having a plurality of lenses and a side surface, and a light-blocking film that is arranged between the plurality of lenses on the lens surface. A curing light is provided to the lens surface as well as to the inside of the substrate through the side surface to cure the light-blocking film.

Abstract: The present invention provides a circuit creation technology that improves conductive line manufacture by adding active and elemental palladium onto the surface of a substrate. The palladium is disposed in minute amounts on the surface and does not form a conductive layer by itself, but facilitates subsequent deposition of a metal onto the surface, according to the pattern of the palladium, to form the conductive lines.

Abstract: A composition for forming an aluminum-containing film includes an organic solvent, and an organic aluminum compound. The organic aluminum compound has a structure represented by a general formula (1). In the general formula (1), each of R1 to R6 is independently a hydrogen atom or a hydrocarbon group, each of R1s, R2s, R3s, R4s, R5s and R6s is identical or different, and optionally each of R1s, R2s, R3s, R4s, R5s or R6s is linked to one another.

Abstract: A method of preparing an organic light-emitting device including: forming an organic emission unit on a substrate; and forming a thin film encapsulation layer including at least one inorganic layer including a low temperature viscosity transition (LVT) inorganic material, the forming the thin film encapsulation layer including forming the at least one inorganic layer, and the forming the at least one inorganic layer including: forming a pre-inorganic layer including the LVT inorganic material on the organic emission unit by heating a source including the LVT inorganic material using plasma in a vacuum and depositing the LVT inorganic material or ions of the LVT inorganic material separated from the source on the organic emission unit; and applying a healing process to the pre-inorganic layer at a temperature greater than a viscosity transition temperature of the LVT inorganic material.

Abstract: According to one embodiment, a lens array is provided with a plurality of lenses, which are formed in an effective area of a substrate, a dam structure, which is formed in an outer periphery of the plurality of lenses, and light-blocking films, which are formed using an ink and positioned between the plurality of lenses and between the plurality of lenses and the dam structure.

Abstract: The invention relates in particular to a method of painting a motor vehicle bodywork part, the method comprising the steps consisting in applying a first component on the part, in allowing the first component to tension on said part during a so-called “flash-off” stage, then in applying a second component on the part, the part being moved by a handler robot in front of a stationary applicator during the two spraying steps and in front of flash-off acceleration means during the flash-off stage. The invention also provides a painting booth having at least one stationary applicator for applying a paint component on a part carried by an arm of a handler robot that is present in the booth, and means for accelerating the flash-off of the part, the means being arranged in the booth in such a manner that the part can enter into the field of action of the acceleration means while being carried by the same handler robot.

Abstract: Method for manufacturing a multilayer structure with a lateral pattern, in particular of an optical grating for application in an optical device for electromagnetic radiation with a wavelength in the wavelength range between 0.1 nm and 100 nm, comprising the steps of (i) providing a multilayer structure, and (ii) arranging a lateral three-dimensional pattern in the multilayer structure, wherein step (ii) of arranging the lateral pattern is performed by means of a method for nano-imprint lithography (NIL), and BF and LMAG structures manufactured according to this method.

Abstract: An optical recording medium production device of the invention include: a rotary table on which a substrate of an optical recording medium is placed; and dropping unit for dropping resin for forming a light transmissive film layer during rotation of the rotary table, wherein the dropping unit drops the resin onto an inside of the substrate and a side surface of the substrate. By applying the production device of the invention, in the spin coat method, a UV curable resin layer can be formed a cross-sectional shape of which is uniform in a whole circumference of the optical recording medium side surface.

Abstract: An apparatus for continuously forming a thin-film layer of organic or inorganic functional material on one or both sides of a flexible substrate via plasma enhanced vacuum vapour deposition.

Abstract: The present invention relates to a method for manufacturing an anti-reflective coating film. The method for manufacturing an anti-reflective coating film is used to form an anti-reflective coating film exhibiting more improved interface adhesion and scratch resistance and excellent anti-reflective effect by a simple process.

Abstract: A plastic article is described having a substrate of a substantially transparent substrate having a thickness of from 0.2 mm to 3.0 mm, and including a thermoplastic composition comprising a polycarbonate and having a melt flow index as defined by ASTM D1238 of 10 g/10 min. to 50 g/10 min. at 300° C. and a 1.2 kg load, the thermoplastic composition including a polycarbonate, the thermoplastic composition comprising 20 mol % to 80 mol % of specified cyclohexylidene-bridged carbonate units and 80 mol % to 20 mol % of specified other carbonate units. The substrate has a hard coat thereon that provides the article with a pencil hardness of at least 5H as determined according to JIS K5400 using a 0.75 kgf load.

Abstract: A highly tensile dielectric layer is generated on a heat sensitive substrate while not exceeding thermal budget constraints. Cascaded ultraviolet (UV) irradiation is used to produce highly tensile films to be used, for example, in strained NMOS transistor architectures. Successive UV radiation of equal or shorter wavelengths with variable intensity and duration selectively breaks bonds in the Si—N matrix and minimizes shrinkage and film relaxation. Higher tensile stress than a non-cascaded approach may be obtained.

Abstract: By producing a resin composition containing (A) an epoxy resin having two or more epoxy groups in one molecule thereof and containing a hexanediol structure, (B) an ultraviolet ray active ester group-containing compound, and (C) an epoxy resin curing accelerator, even in a state where an irregular shape of the surface of an insulating resin layer is small, a high adhesive force to a wiring conductor can be easily revealed.

Abstract: A method of orienting microphase-separated domains is disclosed, comprising applying a composition comprising an orientation control component, and a block copolymer assembly component comprising a block copolymer having at least two microphase-separated domains in which the orientation control component is substantially immiscible with the block copolymer assembly component upon forming a film; and forming a compositionally vertically segregated film on the surface of the substrate from the composition. The orientation control component and block copolymer segregate during film forming to form the compositionally vertically-segregated film on the surface of a substrate, where the orientation control component is enriched adjacent to the surface of the compositionally segregated film adjacent to the surface of the substrate, and the block copolymer assembly is enriched at an air-surface interface.

Abstract: The present disclosure is directed to a method, called herein the “wrap-around” method, of applying polymers to glass articles having one or a plurality of shaped edges. The glass articles have a selected length, selected width and selected thickness which define a first face, a second face and one or a plurality of edges. Circular and oval articles are deemed to have a single edge. Rectangular, square, hexagonal, octagonal, and other shapes having angled corners are deemed to have a plurality of edges defined by the faces and thickness of the glass. The glass articles can be either (1) flat or planar as shown in FIG. 6a, which is sometimes referred to as a two dimensional or 2D article, or (2) three dimensional or 3D article in which the glass article is non-planar as is illustrated in FIG. 7b.

Abstract: Provided are an anti-static and anti-microbial surface treatment agent including a quaternary ammonium salt compound as an active ingredient and a method of preventing a polymer fiber from developing static electricity by using the surface treatment agent. The quaternary ammonium salt compound has excellent anti-static and anti-microbial effects for the prevention or improvement of static electricity in a polymer fiber. Accordingly, the quaternary ammonium salt compound is suitable for use as a fabric softener, or an anti-static agent, and also, provides anti-microbial effects to a polymer fiber.

Abstract: A method for manufacturing a substrate having a textured surface. The method including the steps of: providing a substrate having a surface; applying a coating material onto the surface of the substrate; texturing the coating material on the surface of the substrate to form a textured coating; exposing the textured coating on the substrate to ultraviolet light for a duration of time sufficient to fully cure the textured coating on the substrate; and thereby forming a fully cured textured surface on the substrate.

Abstract: A method is provided to produce an opto-electronic device comprising a substrate, a first electrode layer, a second electrode layer of opposite polarity to said first electrode layer, any interlayers and, between said first and second electrode layers, a first functional material in interfacial contact with a second functional material, wherein the first functional material has the structure of a laterally porous film and the second functional material is a film disposed over and interpenetrating with the film of the first functional material.

Abstract: A composite sheet is manufactured by depositing a multi-layer coating on the outer surface of a substrate, the coating comprising a metal layer and an outer polymeric layer formed from a precursor comprising a composition capable of being polymerized and/or cross-linked by free-radical processes. After the precursor is applied, the composite sheet is exposed to beam radiation and ozone, which both promote conversion of the precursor. The function of the cured polymeric layer includes protecting the metal layer from corrosion. The use of both beam radiation and ozone promotes substantially full conversion and curing of the precursor, even in portions of the substrate that are geometrically shadowed from incident beam radiation.

Abstract: A thin film depositing apparatus and a thin film deposition method using the apparatus. The thin film depositing apparatus includes a chamber configured to have a substrate mounted therein, an ejection unit configured to move in the chamber and to eject a deposition vapor to the substrate, and a source supply unit configured to supply a source of the deposition vapor to the ejection unit.

Abstract: A resin layer formation method and device for making a resin layer uniform on a substrate before lamination or on a substrate is provided. Adhesive is coated at an inner circumference side while rotating a substrate at low speed. A first adhesive layer is formed on the surface of the substrate by rotating at high speed. A step difference section is formed around a rotation center of the substrate by irradiating ultraviolet on an area in the inner circumference side of the first adhesive layer to hardening the area. Adhesive is coated at the rotation center side from the step difference section on the substrate, and a second adhesive layer is formed on the first adhesive layer by rotating the substrate at high speed. The first adhesive layer and the second adhesive layer are integrated to form a uniform adhesive layer.

Abstract: A primer coating composition for a metal substrate is described. The primer has a suitable binder and is characterised in that there is at least one semiconductor photocatalyst dispersed throughout the primer coating composition. A process of coating a metal substrate is also described. The invention extends to the use of a semiconductor photocatalyst as a top-coat to primer adhesion promoter or as a primer to top-coat delamination inhibitor in a primer coating composition.

Abstract: To provide a liquid crystal alignment film having a sufficient alignment-regulating power and high resistance against blue laser beam and having, at the same time, excellent adhesion, and an optical element using it. A liquid crystal alignment film obtainable by bonding, by chemisorption to a substrate, an alignment-regulating precursor which undergoes anisotropic decomposition by irradiation with polarized ultraviolet light, and irradiating the alignment-regulating precursor bonded to the substrate, with polarized ultraviolet light, to let it undergo anisotropic decomposition and exhibit an alignment-regulating power.

Abstract: An optical media such as an optical tape includes a substrate, a pre-format layer on one side of the substrate, and a back side coating. The back side coating is optically transparent and is electrically conductive. One of the substrate and the pre-format layer is between the back side coating and the other one of the substrate and the pre-format layer.

Abstract: A glass-flake loaded organic sealant system is useful for sealing active layers such as those in electronic devices and solar cells.

Abstract: The present invention provides a liquid crystal display device, including an array substrate, a color film substrate and a liquid crystal layer. The color film substrate includes a black matrix and the black matrix is formed by a black electrical conductive adhesive. The present invention also provides a manufacture method of a liquid crystal display device. The present invention adopts the liquid crystal display device and the manufacture method thereof to efficiently eliminate the static electricity and reduce the manufacture cost thereby solving the technical problems of the prior liquid crystal display device having a high cost and being not capable of efficiently eliminating the static electricity.

Abstract: A method of producing a magnesium fluoride coating includes a step of forming a coating by applying a solution containing a fluorine-containing organic magnesium compound represented by the following formula to a base and a step of heat-treating the coating while the coating is being irradiated with a beam of light with a wavelength of 246 nm or less: Mg(CF3—X—COO)2??(1) wherein X represents a single bond or one of —(CF2)n—, —(CH2)m—, and —CH2CF2— that may have a substituent, where n and m each represent an integer of 1 to 4. The temperature of the heat-treating step can be 250° C. or lower. The coating can be irradiated with a beam of light with a wavelength of 185 nm or less.

Abstract: The present invention relates to a method for manufacturing a hard, water-resistant anti-fog coating, and particularly relates to a method for manufacturing a hard, water-resistant anti-fog coating on plastic material. In this method, an organic-inorganic hard adhesion layer and a hydrophilic anti-fog coating film are prepared for manufacturing a hard, water-resistant anti-fog coating. Both of the organic-inorganic hard adhesion layer and the hydrophilic anti-fog coating have C=C double bonds. Therefore, the organic-inorganic hard adhesion layer and the hydrophilic anti-fog coating are adhered to each other tightly. It brings high hardness, high water resistance and good anti-fog effect.

Abstract: Embodiments of the invention provide a method of manufacturing a patterned graphene film. The method comprises the following steps: Step 1: a photoresist layer/electron-beam resist layer is coated on a substrate and patterned, the photoresist layer/electron-beam resist layer in a region for forming the patterned graphene film is removed; Step 2: a solution of oxidized graphene is coated on the substrate formed with the photoresist layer/electro-beam resist layer patterned in Step 1, so that a film of oxidized graphene is formed; Step 3: the substrate obtained in Step 2 is placed in a hydrazine steam, so that the film of oxidized graphene formed in Step 2 is reduced and a graphene film is obtained; and Step 4: the photoresist layer/electron-beam resist layer and the graphene film on the photoresist layer/electrone-beam resist layer are removed, so that the patterned graphene film is obtained.

Abstract: A method of imparting hydrophilicity to a surface of a material, which comprises providing a base material comprising a surface; applying and chemically fixing a siloxane oligomer represented by Chemical Formula 1 to the surface of the base material to form a siloxane-modified surface; and applying a phosphonic acid compound represented by Chemical Formula 2 to the siloxane-modified surface and carrying out a reaction therebetween to form an organosiloxane coating: wherein in Chemical Formula 1, R1, R2, and R3 are the same or different, and are each independently hydrogen or a C1 to C3 alkyl group, A is a single bond or a C1 to C5 alkylene group, and n ranges from 2 to 30; GN[CH2PO3H2]2??Chemical Formula 2 wherein in Chemical Formula 2, G is —CH2PO3H2, a group represented by Chemical Formula 3, or a group represented by Chemical Formula 4 as defined herein.

Abstract: Provided are a method of producing an antireflection film having a low reflectance, the film using hollow particles having good shape uniformity, and a lens. The method includes: applying, onto the base material, a dispersion containing core-shell particles each using an organic polymer as a core and silica as a shell; drying the dispersion to form a film containing the core-shell particles; and removing the organic polymer through irradiation of the film containing the core-shell particles with ultraviolet light to turn the core-shell particles into hollow particles.

Abstract: An LCD device includes first and second substrates, an alignment layer formed over at least one of the substrates, and a liquid crystal layer formed between the substrates. The alignment layer is formed of a mixture of rubbing alignment and UV alignment materials. A method of fabricating the LCD device includes preparing first and second substrates; coating an alignment layer over at least one of the substrates; performing a rubbing process on the substrate coated with the alignment layer; and irradiating polarized UV rays onto the substrate coated with the alignment layer, wherein the alignment layer is formed of a mixture of rubbing alignment a UV alignment materials. The rubbing process obtains high anchoring energy is obtained, thereby preventing afterimages. Also, the process of irradiating the polarized UV rays eliminates the problem of light leakage.

Abstract: Provided is a color display element which employs a conventional system of monochrome electronic paper without degrading the degree of brightness and with ease and lower costs. Also provided is a method of producing a color display element including a pair of opposing substrates having electrodes, charged display bodies of white color and black color which are enclosed between the opposing substrates, and a color filter which is disposed on one of the opposing substrates, the method including forming a color filter disposed on a viewing side by forming, first, colored regions of at least three colors of blue, green, and red by an inkjet method on a transparent support substrate, and forming remaining regions other than the colored regions so as to be colorless or transparent.

Abstract: A system and method for optical calibration discs includes dispensing a resist layer on a portion of a substrate. A surface of the substrate and a topographically patterned surface of predetermined objects of a template are contacted together, wherein the contacting causes the resist layer between the portion of the substrate and the template to conform to the topographically patterned surface, and the resist layer includes nano-scale voids. The nano-scale voids are reduced by longer spread time, thinner resist, and removal of the residual resist layer together with the voids by using a descum step. The resist layer is hardened into a negative image of the topographically patterned surface, wherein the negative image includes surfaces that are operable to be individually measured by an optical reader. The substrate and the template are separated, wherein the resist layer adheres to the surface of the substrate.

Abstract: A highly transparent and electrically conductive substrate is made by applying a conductive mesh over a transparent substrate, depositing a UV-curable transparent material over the conductive mesh and the transparent substrate, and exposing the UV-curable transparent material to a directional UV light from a UV light source positioned so that the UV light emitted from the UV light source travels through the transparent substrate before being received by the UV-curable transparent material, wherein the UV-curable transparent material is cured in response to exposure from the UV light except for those portions of the UV-curable transparent material masked from exposure to the UV light by the conductive mesh. Uncured portions of the UV-curable transparent material are removed, and a transparent conductive material layer is deposited over the cured UV-curable transparent material and conductive mesh.

Abstract: Apparatus for curing the coating of a workpiece (1), which comprises at least one tank (2) with inert gas heavier than air into which the workpiece (1) is inserted, and at least one UV-radiation source (3) that generates radiation that falls on the workpiece (1) to bring about the curing. The apparatus also comprises an extraction area (4), a recirculation circuit (5) and an insertion area (6), where, respectively, inert gas is extracted from the tank (2), recirculated, and reintroduced into the tank (2). At least one inert gas cooling member (7) is situated in the recirculation circuit (5), thus preventing the inert gas inside the tank (2) from overheating and reducing the risk of instability in the inert gas atmosphere.