Abstract: A process for passivation of strip steel plate, having the following steps: electrochemical treatment of the black plate by passing the black plate through an electrolyte to form an inert steel surface; rinsing the black plate; and application of an aqueous chromium-free treatment solution to at least one surface of the black plate to form a conversion layer that protects against corrosion and an adhesion layer for paints and organic coating materials. The black plate treated in accordance with this process is characterized by high corrosion resistance and has good bonding capacity for paints and organic coatings and therefore is very suitable as a substitute for tin-free steel (TFS or ECCS) and tinplate for the production of packagings, in particular cans. In contrast to the traditional manufacturing and passivation processes for tin-free steel and tinplate, no chromium VI, which is environmentally hazardous and hazardous to health, is used in this process.

Abstract: The present invention provides a monolithic integrated lattice mismatched crystal template and a preparation method thereof by using low-viscosity material, the preparation method for the crystal template includes: providing a first crystal layer with a first lattice constant; growing a buffer layer on the first crystal layer; below the melting point of the buffer layer, growing a second crystal layer and a template layer by sequentially performing the growth process of a second crystal layer and the growth process of a first template layer on the buffer layer, or growing a template layer by directly performing a first template layer growth process on the buffer layer; melting and converting the buffer layer to an amorphous state, performing a second template layer growth process on the template layer grown by the first template layer growth process at the growth temperature above the glass transition temperature of the buffer layer, sequentially growing a template layer until the lattice of the template laye

Abstract: Provided is a silver-plated coated body that is excellent in interlayer adhesion and tarnish resistance. The silver-plated coated body has a silver film layer and a topcoat layer as essential layers on a substrate, the topcoat layer containing at least one kind selected from thiourea and thiourea derivatives, and at least one kind selected from thiol organic acids and thiol organic acid derivatives.

Abstract: Disclosed is a process and apparatus for preparing a substrate having a high coefficient of friction on a surface, and the high friction substrate. A pre-process of sanding can be used, followed by thermal wire coating of the sanded surface. The surface can have a static and dynamic coefficient of friction greater than or equal to than 0.85.

Abstract: The composition for coating of a surface intended to be exposed to a metal melt is disclosed. The composition essentially consists of: 8-18 wt-% of a refractory component; 50-75 wt-% of solvent, preferably water; 10-20 wt-% of an inorganic binder; 0-10 wt-%, preferably 2-10 wt-%, of an organic binder; 0.3-7 wt-%, preferably 2-6 wt-%, more preferably, 3-5 wt-% of pyrite; and optionally up to 10 wt-%, preferably up to 5 wt-%, of additional additive or additives. The composition results in a coating on a surface, which coating is able to reduce the dissolved elemental magnesium content in a metal melt to which the surface is exposed.

Abstract: A method and apparatus for forming a sandwich structure is presented. A sandwich structure comprises a metallic core layer and a thermoplastic layer on a first side of the metallic core layer. The thermoplastic layer is consolidated against the first side of the metallic core layer.

Abstract: The present invention is to provide a method of manufacturing a resin-encapsulated electronic component and an apparatus for manufacturing a resin-encapsulated electronic component that enable the manufacture of a resin-encapsulated electronic component including a plate-like member in a simple manner at low cost. The method of manufacturing a resin-encapsulated electronic component, the resin-encapsulated electronic component including a plate-like member 13, the method includes: placing a resin 15 on the plate-like member 13; transferring the resin 15 to a position of a die cavity 17a of a molding die in a state where the resin 15 is placed on the plate-like member 13; and performing resin-encapsulation of an electronic component by subjecting the resin 15 to compression molding together with the plate-like member 13 and the electronic component in a state where the electronic component is soaked in the resin 15 placed on the plate-like member 13 in the die cavity 17a.

Abstract: A transparent conductive film contains a metal filler, a colored compound adsorbed to the surface of the metal filler, and at least one of thiols, sulfides, and disulfides adsorbed to the surface of the metal filler. When the terminal on the metal filler side of the colored compound is not any of thiols, sulfides, and disulfides, at least one of colorless thiols, sulfides, and disulfides is adsorbed to the surface of the metal filler. According to this transparent conductive film, an increase in resistance can be suppressed while suppressing diffuse reflection of light on the surface of the metal filler.

Abstract: The invention relates to a component (1) having a coating (3) that is metallurgically bonded on as well as thermally sprayed on and re-melted. In order to prevent wear phenomena from continuing to occur when force impacts occur in the component (1) and further surface stress occurs, the invention provides that the coating (3) is provided with a thermal spray layer (4).

Abstract: A monoaxially oriented film including a propylene-based random copolymer and at least about 3 wt % of a low density polyethylene which is oriented at least about 2.5 times in one direction and exhibits excellent linear directional tear properties parallel to the orientation direction and excellent heat seal performance in terms of high heat seal strengths and low seal initiation temperature. This film formulation and orientation is suitable for pouch applications requiring an “easy-tear” linear tear feature and excellent hermetic seal properties.

Abstract: The present invention provides a high dielectric film for a film capacitor obtained by molding a film forming composition for a film capacitor comprising a thermoplastic resin (A) and surface-treated high dielectric inorganic particles (B) obtained by treating the surfaces of high dielectric inorganic particles (b1) having a dielectric constant (20° C., 1 kHz) of 100 or more with a low dielectric compound (b2) having a dielectric constant (20° C., 1 kHz) of 10 or less. This high dielectric film for a film capacitor can restrain the decrease of electrical insulating property, in spite of the high dielectric inorganic particles being dispersed at a high filling rate.

Abstract: Disclosed is a thermosetting resin composition including a thermosetting aromatic oligomer represented by the following Chemical Formula 1, a hollow particle, and solvent, and a board comprising the same. In the above Chemical Formula 1, wherein B, L1, L2, Z1 and Z2 are the same as in defined in the specification.

Abstract: A monoaxially oriented film including a metallized layer; a gas barrier layer; and a propylene-based random copolymer and at least about 3 wt % of a low density polyethylene which is oriented at least about 2.5 times in one direction and exhibits excellent linear directional tear properties parallel to the orientation direction and excellent heat seal performance in terms of high heat seal strengths and low seal initiation temperature. This film formulation and orientation is suitable for pouch applications requiring high gas and moisture barrier, an “easy-tear” linear tear feature, and excellent hermetic seal properties.

Abstract: A core or sub-composite structure is provided including a dielectric layer between a first conductive film and a second conductive film. The first conductive film may include a first peelable/removable cover layer formed on or coupled to a first conductive layer. The second conductive film may include a second peelable/removable cover layer formed on or coupled to a second conductive layer.

Abstract: Bonding of substrates including metal-dielectric patterns on a surface with the metal raised above the dielectric, as well as related structures, are disclosed. One structure includes: a first substrate having a metal-dielectric pattern on a surface thereof, the metal-dielectric pattern including: a metal having a concave upper surface; and a dielectric having a substantially uniform upper surface, wherein the metal on the first substrate is raised above the dielectric on the first substrate; and a second substrate bonded with the first substrate, the second substrate including: a dielectric; and a metal positioned substantially below the dielectric of the second substrate, wherein the first substrate and the second substrate are bonded only at the metal from the first substrate and the metal from the second substrate.

Abstract: The present invention is made to provide a transparent electrode having both electrical conductivity and light transmissibility, and improve the performance of an electronic device and an organic electroluminescence element. A transparent electrode (1) includes a nitrogen-containing layer (1a) and an electrode layer (1b) formed adjacent to the nitrogen-containing layer (1a). The electrode layer (1b) is formed using silver or an alloy having silver as a main component. The nitrogen-containing layer (1a) is composed of a compound that satisfies Formulas (1) and (2).

Abstract: Antimicrobial devices such as molded components can include surfaces which have a microbial field disruptive hyper-conductive layer covered by a dielectric surface layer, to continuously disinfect said surfaces. Also, the present invention relates to generally antimicrobial dressings and more particularly to dermal dressings and bandages providing antiseptic disinfection, comprising typical modern dressings and bandages stratified in close proximity to microbial field disruptive hyper-conductive elements or alloys which deactivate microbes by disrupting the electric field generated by and used by the microbes, and isolated the wound or surgical site tissue from said conductors with a layer or layers of dielectric film.

Abstract: An intumescent coating composition having improved char yield, while maintaining its physical, mechanical, and esthetic properties comprises (a) particulate poly(phenylene ether), wherein the mean particle size of the poly(phenylene ether) is 1 to 100 micrometers; (b) a film-forming binder; (c) an acid source; (d) a blowing agent; and (e) optionally, a carbon source other than the particulate poly(phenylene ether); wherein polyolefins, homopolystyrenes, rubber-modified polystyrenes, styrene-containing copolymers, and hydrogenated and unhydrogenated block copolymers of an alkenyl aromatic compound and a conjugated diene are all absent from the composition.

Abstract: A layered insulation apparatus and method of making that contains a multiple layer insulation that has top and bottom outside moisture barrier layers, with at least two flame retardant layer around a center metal layer. The metal layer may be two metal sheets with a scrim there-between. The metal layer is highly polished to reflect heat. The metal layer is protected from heat by the flame retardant layers and protected from moisture by the outside moisture barrier layers. A sound abatement layer may optionally be layered on top of the first moisture barrier layer.

Abstract: Provided are a method for manufacturing a flexible display apparatus, which allows for easy separation of a flexible substrate from its supporting carrier as well as allowing easy handling of the flexible substrate during processing of the flexible substrate while it is on its supporting carrier. Also provided is a flexible display apparatus manufactured by the method. The method includes forming an adhesive layer including a metallic tin where the adhesive layer is disposed on a supportive carrier and disposing a flexible substrate on the adhesive layer such that the flexible substrate is affixed to the supporting carrier with the adhesive layer interposed therebetween. The method further includes separating the flexible substrate from the carrier by transformatively stressing (disintegration-wise stressing) the adhesive layer for example by means of temperature lowering.

Abstract: A composite pane having a sun protection and a heat protection function is described. The composite pane has an outer pane having an outer surface and an inner surface, an inner pane having an outer surface and an inner surface, and a thermoplastic intermediate layer, having at least a sun protection coating on at least the inner surface, the outer surface, or in the thermoplastic intermediate layer, and a heat protection layer on the inner surface. The sun protection layer has at least one functional layer containing at least silver, and the heat protection layer has at least one functional layer containing at least one metal of the group consisting of niobium, tantalum, molybdenum, and zirconium.

Abstract: The present application discloses a composite substrate used for GaN growth, comprising a thermally and electrically conductive layer (1) with a melting point greater than 1000° C. and a mono-crystalline GaN layer 2 (2) located on the thermally and electrically conductive layer (1). The thermally and electrically conductive layer (1) and the mono-crystalline GaN layer 2 (2) are bonded through a van der Waals force or a flexible medium layer (3). The composite substrate can further include a reflective layer (4) located at an inner side, a bottom part, or a bottom surface of the mono-crystalline GaN layer 2. In the disclosed composite substrate, iso-epitaxy required by GaN epitaxy is provided; crystalline quality is improved; and a vertical structure LED can be directly prepared. Further, a thin mono-crystalline GaN layer 2 greatly reduces cost, which is advantageous in applications.

Abstract: A method for coating a metal substrate with a white, off-white or gray colored autodeposited coating comprising water, polymeric resin, HF and pigment particles comprising a core of titanium dioxide, an intermediate zirconia and/or alumina layer, and an outer organic layer, optionally the particles are treated with an anionic surfactant.

Abstract: A transparent electrode includes a conductive layer and an intermediate layer disposed adjacent to the conductive layer. The intermediate layer contains a diazacarbazole derivative represented by the following general formula (1). The conductive layer is composed of silver as a main component. In the general formula (1), E1 to E8 each represent C(R1) or N with one of E1 to E4 being N and one of E5 to E8 being N, and R and R1 each represent a hydrogen atom or a substitute. [Chem.

Abstract: Metal-coated polymer articles containing structural substantially porosity-free, fine-grained and/or amorphous metallic coatings/layers optionally containing solid particulates dispersed therein on polymer substrates, are disclosed. The substantially porosity-free metallic coatings/layers/patches are applied to polymer or polymer composite substrates to provide, enhance or restore vacuum/pressure integrity and fluid sealing functions. Due to the excellent adhesion between the metallic coating and the polymer article satisfactory thermal cycling performance is achieved. The fine-grained and/or amorphous metallic coatings are particularly suited for strong and lightweight articles, precision molds, sporting goods, aerospace and automotive parts and other components exposed to thermal cycling and stress created by erosion and impact damage.

Abstract: An object of the present invention is to provide a substrate with a multilayer reflective film and the like used in the manufacturing of a reflective mask blank for EUV lithography which is to be subjected to dry etching with a Cl-based gas, wherein in the substrate with the multilayer reflective film, the loss of protective films by the dry etching and subsequent wet cleaning is very limited. The present invention is a substrate with a multilayer reflective film used in the manufacturing of a reflective mask blank for EUV lithography, comprising a substrate, a multilayer reflective film disposed on the substrate to reflect EUV light, and a protective film disposed on the multilayer reflective film to protect the multilayer reflective film, the protective film includes an alloy containing at least two metals, the alloy being an all-proportional solid solution.

Abstract: A composition comprises a metal powder. The composition further comprises a solder powder which has a lower melting temperature than a melting temperature of the metal powder. The composition further comprises a polymer and a carboxylated-polymer different from the polymer. The carboxylated-polymer is useful for fluxing the metal powder and cross-linking the polymer. The composition further comprises a dicarboxylic acid and a monocarboxylic acid. The acids are useful for fluxing the metal powder. The composition may be used for forming a conductor. The conductor may be used for current trans and/or electrical connection. An article comprises a substrate and the conductor disposed on and in electrical contact with the substrate. The article may be used for various applications, such as for converting light of many different wavelengths into electricity. Examples of such articles include photovoltaic (PV) cells and circuit boards.

Abstract: An object is to provide the formulation of a copper particulate dispersion in which copper particulates are dispersed. The copper particulate dispersion includes copper particulates, at least one kind of a dispersion vehicle containing the copper particulates, and at least one kind of dispersant which allows the copper particulates to disperse in the dispersion vehicle. The copper particulates have a center particle diameter of 1 nm or more and less than 100 nm. The dispersion vehicle is a polar dispersion vehicle. The dispersant is a compound having at least one acidic functional group, which has a molecular weight of 200 or more and 100,000 or less, or a salt thereof. Whereby, the dispersant has compatibility with dispersion vehicle and a surface of copper particulates is coated with dispersant molecules, and thus the copper particulates are dispersed in the dispersion vehicle.

Abstract: A high vacuum component, e.g. a vacuum chamber wall or a component that is operated or positioned within a vacuum chamber in use is described. The component is substantially formed of a layered material comprising a fibrous composite material layer having a surface that is coated with a copper intermediate layer and an impermeable outer layer of nickel. In use the outer layer is exposed to a high vacuum.

Abstract: A coated pigment that includes polymer encapsulations which act as a pigment dispersant and film forming agent, coating systems that include the coated pigment and methods for producing the coated pigment and the coating system are described. The polymer encapsulations of the coated pigments allow the coated pigments that are included in the coating system to be dispersed without the addition of any other dispersants and/or resins. Thus, the disclosed coated pigments simplify the process of making coating systems. The disclosed coated pigments also extend the shelf-life of the coating systems, and provide a final coating with enhanced pigment orientation and aesthetics.

Abstract: Getter systems are provided including one or more deposits of getter materials, wherein at least one of the deposits is in contact with a layer of a material having H2O transport properties.

Abstract: Metal-clad polymer articles containing structural fine-grained and/or amorphous metallic coatings/layers optionally containing solid particulates dispersed therein. The fine-grained and/or amorphous metallic coatings are particularly suited for strong and lightweight articles, precision molds, sporting goods, automotive parts and components exposed to thermal cycling although the CLTE of the metallic layer and the one of the substrate is mismatched. The interface between the metallic layer and the polymer is suitably pretreated to withstand thermal cycling without failure.

Abstract: To provide a production process to produce a laminate having excellent moisture resistance and abrasion resistance, and a laminate. The process for producing a laminate 1 comprises a first step of forming a dielectric layer 121, a metal layer 122 and a dielectric layer 121 in this order on a transparent substrate, and a second step of, after the first step, forming a tin zinc oxide layer 13 containing an oxide of tin and zinc as the main component. Formation of the tin zinc oxide layer 13 in the second step is carried out by sputtering using a metal target containing tin and zinc as the main component in a gas atmosphere in which a gas containing carbon atoms substantially functions as an oxidizing gas. Formation of the dielectric layer 121 in the first step is carried out in a gas atmosphere in which a gas containing no carbon atom substantially functions as an oxidizing gas.

Abstract: A coating process and coated article are disclosed. The coating process includes positioning an article relative to an inductor, heating the article with the inductor, then applying a coating material over the article to form a crystalline coating. The heating of the article increases a first temperature of a surface of the article to a second temperature favoring crystal formation. Another coating process includes positioning an article, uniformly heating a surface of the article to a second temperature favoring crystal formation, then applying an environmental barrier coating material over the surface of the article to form a crystalline environmental barrier coating. The application of the environmental barrier coating is performed through air plasma spray deposition. The coated article includes an article having a complex geometry, and a crystalline coating applied on a surface of the article. The crystalline coating includes increased resistant to delamination.

Abstract: An electronic apparatus and a method for manufacturing the same are disclosed. The electronic device of the present invention comprises: a substrate with a first surface and a second surface; an electronic unit layer disposed on the first surface of the substrate; a residue layer disposed on the second surface of the substrate, wherein a material of the residue layer comprises: a compound containing at least one functional group selected from the group consisting of aryl, nitro and ketone.

Abstract: A substrate structure is provided. The substrate structure includes a substrate, a first decoration layer, and a light absorption layer. The first decoration layer is disposed on the substrate. The light absorption layer is disposed on the first decoration layer, and the first decoration layer is located between the substrate and the light absorption layer. The material of the light absorption layer includes a semiconductor metal alloy.

Abstract: A composition useful as a bond coat is provided. The composition includes about 3% to about 7% chromium, about 10% to about 30% nickel, about 12% to about 18% aluminum, about 0.0005% to about 0.15% yttrium, about 0.0% to about 16% strengtheners, balance cobalt, and incidental impurities. Also provided is a component including a substrate having at least one layer of the composition applied thereto.

Abstract: A process for the production of a dark-color multi-layer coating, comprising the successive steps: (1) applying an NIR-opaque coating layer A? from a pigmented, solvent- or waterborne coating composition A to a substrate, (2) applying a coating layer B? from a pigmented coating composition B onto the substrate provided with coating layer A?, wherein the pigment content of coating composition A consists 90 to 100 wt. % of at least one aluminum flake pigment and 0 to 10 wt. % of at least one further pigment, which is selected in such a way that NIR-opaque coating layer A? exhibits low NIR absorption, wherein the pigment content of coating composition A comprises <90 wt. % of 10 to 80 nm thick aluminum flake pigments, wherein the pigment content of coating composition B consists 50 to 100 wt. % of at least one black pigment with low NIR absorption and 0 to 50 wt.

Abstract: A metal material of the present invention is composed of an underlying metal and a phosphate compound-based film which is disposed on the surface of the underlying metal and has a surface part, in which the surface part of the phosphate compound-based film contains Zr.

Abstract: A method of manufacturing a multi-layer thin film is provided. The method includes modifying a surface of a plastic object by plasma treatment, depositing at least one hardness-enhancing layer on the plastic object, and depositing a color layer on the hardness-enhancing layer. The method may further include depositing a protective layer on the color layer.

Abstract: Some novel features pertain to a substrate that includes a first core layer, a second core layer laterally located to the first core layer in the substrate, a first inorganic core layer (e.g., glass, silicon, ceramic) laterally positioned between the first core layer and the second core layer, the first inorganic core layer configured to be vertically aligned with a die configured to be coupled to the substrate, and a dielectric layer covering the first core layer, the second core layer and the first inorganic core layer. In some implementations, the first inorganic core layer has a first coefficient of thermal expansion (CTE), the die has a second coefficient of thermal expansion, and the first core layer has a third coefficient of thermal expansion (CTE). The first CTE of the first inorganic core layer closely matches the second CTE of the die in order to reduce the likelihood of warpage.

Abstract: Disclosed herein is a method of forming a multilayer thin film by depositing target particles, detached from a target by plasma discharge of inert gas, on a metal object using a multilayer thin film deposition apparatus and a multilayer thin film formed by the method. More specifically, a sputtering deposition apparatus is used as the multilayer thin film deposition apparatus. The method includes coating a metal object with a coating layer, depositing at least one hardness-enhancing layer on the coating layer, and depositing a color layer on the at least one hardness-enhancing layer.

Abstract: The present invention provides a compound heat sink, mainly comprising a graphite layer and a metal layer. The graphite layer has a first embedding structure on a surface; the metal layer has a second embedding structure on a surface and corresponding to the first embedding structure. The graphite layer and the metal layer are bonded by the first and second embedding structures for increasing the bonding strength between two heterogeneous materials as well as reducing the interfacial heat resistance. Thereby, the stability of heat dissipation performance can be improved.

Abstract: A laser-engraveable composition comprises one or more elastomeric rubbers including at least 10 parts of one or more CLCB EPDM elastomeric rubbers, based on parts per hundred of the total weight of elastomeric rubbers (phr). The laser-engraveable composition further comprises 2-30 phr of a near-infrared radiation absorber and either 1-80 phr of an inorganic, non-infrared radiation absorber filler, or a vulcanizing composition that comprises a mixture of at least two peroxides. One first peroxide has a t90 value of 1-6 minutes as measured at 160° C., and a second peroxide has a t90 value of 8-20 minutes as measured at 160° C. This laser-engraveable composition can be used to form various flexographic printing precursors that can be laser-engraved to provide relief images in flexographic printing plates, printing cylinders, or printing sleeves.

Abstract: [Object] To provide a medical instrument capable of more effectively inhibiting a cracking and separation than conventional ones. [Solution Means] A stent comprising a substrate layer 10 of which at least the surface is composed of a metal material, a carbon compound layer 12 that is formed so as to coat the surface of the substrate layer 10 and that contains at least one metal element, a first DLC layer 14 that is formed so as to coat the surface of the carbon compound layer 12 and that is free of fluorine, and a second DLC layer 16 that is formed so as to coat the surface of the first DLC layer 14 and that contains fluorine. The stent being constituted to satisfy the relationship defined by the expression of “A1>A2>A3”, wherein A1 is a surface free energy of the carbon compound layer 12, A2 is a surface free energy of the first DLC layer 14, and A3 is a surface free energy of the second DLC layer 16.

Abstract: The invention relates to a magnetic field shield for electromagnetic fields, preferably in the frequency range of 50 Hz to 200 kHz, essentially comprising a composite sheet formed from at least three layers arranged one above the other, wherein at least one of the layers is made of electrical steel sheet or electrical steel strip. In order to provide at low cost such a magnetic field shield that has low weight and good shielding effect, it is proposed that at least one of the layers is made of sheet steel and at least one of the layers is made of plastic and/or elastomer, wherein the at least one layer made of plastic and/or elastomer integrally bonds together the at least one layer made of electrical steel sheet/electrical steel strip and the at least one layer made of sheet steel.

Abstract: An Ag alloy film for use in reflective electrodes is provided, which has a low electrical resistivity and a high reflectance that are almost at the same levels as those of an Ag film, and has excellent oxidation resistance. An Ag alloy film for reflective electrodes, which can be used in a reflective electrode and is characterized in that at least one element selected from the group consisting of In and Zn is contained in an amount of 0.1 to 2.0 atomic %.

Abstract: A method for arranging a coating, in particular a hardfacing, on a component, in particular a TiAl drive unit component, is disclosed. The coating comprises a metallic coating material. A green body is formed with the coating material, which is arranged in the presence of a solder on the component and is formed into a coating by a combined solder-sintering process and is fixed on the component.

Abstract: The invention relates to an aluminum alloy strip with improved surface optics, which is fabricated via hot and/or cold rolling, and consists of a type AA 3xxx, AA 5xxx, AA 6xxx or AA 8xxx aluminum alloy. The object of proposing an aluminum alloy strip that is suitable for attractive and precious surface optics despite the elevated percentage of alloy constituents is achieved in that, after degreasing, the finish-rolled aluminum alloy strip exhibits an increase in the luminance value L*(?L) in relation to the rolled-greasy state of more than 5 while measuring the color of the surface in the CIE L*a*b* color space using a standard illuminant D65 and a normal observation angle of 10°, excluding direct reflection in 45°/0° geometry.

Abstract: According to various embodiments, an electrode may include at least one layer including a chemical compound including aluminum and titanium.