Abstract: An apparatus includes a first steel component having a first surface, a second steel component having a second surface, a corrosion resistant coating on at least one of the first and second surfaces, and an adhesive bonding the first and second components together. The corrosion resistant coating can be electrically conductive.

Abstract: A layered material 1 includes two metal sheets 2,3 and one ceramic sheet 4, wherein the metal sheets 2,3 and the ceramic sheet 4 are stacked so that the ceramic sheet 4 is disposed between the two metal sheets 2,3, and then bonded together through spark plasma sintering. The difference in melting temperature between the metal sheets 2 and 3 is 140° C. or less. The layered material 1 is produced by stacking two metallic sheets 2,3 that have a difference in melting temperature of 140° C. or less and the ceramic sheet 4 so that the ceramic sheet 4 is placed between the both metal sheets 2,3, then disposing the stacked structure of the metal sheet 2,3 and the ceramic sheet 4 between a pair of electrodes in a spark plasma sintering device, and bonding the metal sheets 2,3 and the ceramic sheet 4 by applying a pulse current between the electrodes while maintaining the conduction between the electrodes.

Abstract: Known protective layers having a high chromium content, as well as silicon, have brittle phases that become additionally brittle under the influence of carbon during use. A protective layer including the composition of 18% to 20% cobalt, 6% to 8% aluminum, 0.5% to 0.7% yttrium, 22% to 26% chromium, and the remainder nickel is provided.

Abstract: Light weight composites with high flexural strength comprise epoxy foam sandwiched between two layers of facing material have high strength and low weight and can be used to replace steel structures. The facing layer may be fibrous material especially glass or carbon fibers, the facing material is preferably embedded into the epoxy matrix. Alternatively they may be matching box structures or concentric metal tubes. The sandwich structures may be prepared by laying up the fiber; coating and/or impregnating the layer with epoxy resin, laying a layer of heat activatable foamable epoxy material, providing a further layer of the fibrous material optionally coated and/or impregnated with epoxy resin on the foamable material and heating to foam and cure the epoxy materials. Alternatively they may be formed by extrustion of the foamable material between the surface layers.

Abstract: A component assembly for use in living tissue comprises: a ceramic part; a metal part, e.g., a titanium metal; and a palladium (Pd) interlayer for bonding said ceramic part to the metal part. By applying sufficient heat to liquify a palladium-titanium interface, the Pd interlayer is used to braze the ceramic part to the titanium part to yield a hermetic seal.

Abstract: Certain examples disclosed herein are directed to devices that include a substrate and conductor disposed on the substrate. In some examples, each of the conductor and the substrate may include materials that are mutually insoluble in each other. In other examples, the conductor may further comprise a substantially pure metal. In certain examples, the disposed conductor may be configured to pass adhesion tape test ASTM D3359-02. Methods of forming the conductors are also provided.

Abstract: The invention concerns an under-roof screen (100) comprising: a first layer (102) produced from a first metallic or metallized material forming a thermal reflection barrier; a second layer (108) produced from a second woven material bonded to the first layer (102); a third layer (106) produced from a third insulating material and bonded to the second layer (108); and a fourth layer (104) produced from a fourth metallic or metallized material forming a thermal reflection barrier and bonded to the third layer (106); the first layer (102) and the second layer (108) being provided with micro-perforations (110) providing permeability to water vapor and impermeability to water and the fourth layer (104) being provided with perforations (112) providing permeability to water vapor.

Abstract: The present invention relates to an apparatus with a structured hard chrome layer electrodeposited onto a work-piece, the structured hard chrome layer being cup-shaped and/or labyrinth-like and/or column-shaped. The structured hard chrome layer can be electrodeposited from an electrolyte onto the work-piece, said electrolyte containing (a) a Cr (VI) compound in an amount corresponding to 50 g/l to 600 g/l of chromic acid anhydride; (b) 0.5 g/l to 10 g/l of sulphuric acid; (c) 1 g/l to 20 g/l of aliphatic sulphonic acid, comprising 1 to 6 carbon atoms; and (d) 10 g/l to 200 g/l of at least one compound forming a dense cathode film, said compound being selected from among ammonium molybdate, alkali molybdate and alkaline earth molybdate, ammonium vanadate, alkali vanadate and alkaline earth vanadate, ammonium zirconate, alkali zirconate and alkaline earth zirconate.

Abstract: A non-cadmium multi-layered composite coating is disclosed. Such coating achieves desirable lubricity, retains electrical conductivity, meets high performance industry standards for corrosion resistance, and avoids certain environmental and health hazards. Further disclosed are methods of applying such coating on various substrates using a combination of electrolytic and electro-less plating techniques. Such coating may be advantageously applied in machining and electrical interconnects, and are particularly useful in the defense and consumer electronics and appliances industries.

Abstract: The invention relates to a decorative part (1, 3, 5) including several stones (2) and a device (7, 7?, 47, 47?) for securing the stones (2) in relation to each other. According to the invention, the securing device (7, 7?, 47, 47?) includes a single electrodeposited base (9, 9?, 49, 49?) whose shape matches one part of the stones, allowing all the stones (2) to be attached in relation to each other without any stress, and the girdles (6) of the stones (2) are mounted edge-to-edge in relation to each other so that said single base is concealed. The invention also relates to the method for manufacturing a part (1, 3, 5) of this type. The invention concerns the field of pieces or jewellery or timepieces.

Abstract: Disclosed is a copper foil which has excellent high frequency characteristics and heat resistance, while achieving high heat-resistant adhesion to a resin substrate at the same time. Specifically disclosed is a heat-resistant copper foil which has a configuration wherein a first roughened surface layer which has been treated by a first roughening treatment by copper metal, a second roughened surface layer which has been treated by a second roughening treatment by copper metal, and a third treated surface layer which has been treated by a third treatment process by zinc metal are sequentially provided on one surface of an untreated copper foil.

Abstract: A multilayer substrate includes a base layer, a coating layer and an intermediate layer positioned between the base layer and the coating layer. The intermediate layer contains chromium and nitrogen. A content of the chromium in the intermediate layer gradually decreases from the base layer to the coating layer.

Abstract: Disclosed is a structure of electrolessly palladium (Pd) and gold (Au) plated films on a bonding pad, comprising a Pd plated layer on the bonding pad; and an Au plated layer on the Pd plated layer. Also disclosed is an assembled structure formed of the electrolessly Pd—Au plated films wire-bonded with a copper (Cu) or Pd—Cu wire to the Au plated layer. In addition, a process for producing the structure of the electrolessly Pd—Au plated films and an assembling process for the assembled structure are disclosed. According to the present invention, the Pd plated layer is used to replace the conventional nickel layer so as to enhance the wire-bonding strength between the Cu or Pd—Cu wire and the bonding pad.

Abstract: A metal substrate for a solar battery capable of inhibiting power generation efficiency of a unit solar cell from decrease due to a defect of the unit solar cell is provided. This metal substrate (1) for a solar battery includes a cladding material having a first metal layer (11) with a first surface (11a) formed with a unit solar cell (2) and a second metal layer (12) bonded to the first metal layer on a second surface (11b) opposite to the first surface, while a kurtosis (Rku) serving as an index indicating surface roughness of the first surface is not more than 7.

Abstract: The present invention relates to a brass-plated steel cord capable of further improving initial adhesiveness and heat-resistant adhesiveness between a coating rubber and a steel cord and also imparting excellent durability to a resulting rubber article, and more particularly to a brass-plated steel cord, wherein an outermost surface thereof contains 0.3 to 1.7 atomic % of phosphorus, 4.93 to 14 atomic % of zinc, and 0.01 to 2.0 atomic % of a metal having an ionization tendency lower than that of zinc and higher than that of copper as measured by XPS (X-ray photoelectron spectroscopy), and an amount of zinc in the outermost surface is 30 to 90 atomic % based on 100 atomic % of a total amount of zinc and copper.

Abstract: A process for treating the surface of aluminum or aluminum alloy comprises providing a substrate made of aluminum or aluminum alloy. Then a zinc-plating layer is formed on the substrate by electroless plating with a zinc electroless plating solution, and a ceramic coating comprising refractory compound is next formed on the zinc-plating layer using physical vapor deposition.

Abstract: A coating for a cutting tool, which includes a plurality of mutually superposed layers, characterised in that the coating has an outer cover layer with a first layer portion of metallic aluminium or an aluminium alloy and a second layer portion arranged thereover of aluminium oxide or a mixed oxide which contains aluminium and at least one further metal.

Abstract: A method by which a steel component can be produced, which is provided with a metallic coating which adheres well and which provides protection against corrosion, from a flat steel product produced from a steel material containing 0.3-3 wt.-% manganese and having a yield point of 150-1100 MPa and a tensile strength of 300-1200 MPa coated with an anti-corrosion coating which comprises a coating of ZnNi alloy which is electrolytically deposited on the flat steel product, which coating is composed in a single phase of ?-ZnNi phase and which contains, as well as zinc and unavoidable impurities, 7-15 wt.-% nickel.

Abstract: A bathroom appliance is provided having a substrate made of metal or plastic and a coating, it is provided to consecutively electroplate metal layers made of copper, an alloy of copper and tin, and chromium and to subsequently apply a cover layer which is made of at least one of the elements of chromium, titanium, zirconium, gold, silver or platinum or is made of a chemical combination of the elements of titanium or chromium and nitrogen and, optionally, carbon, the cover layer being produced on the electroplated chromium layer by means of a PVD method.

Abstract: A film structure includes a metal substrate, a metal film formed on the metal substrate, an insulating transparent optical film formed on the metal film. The metal film eliminates an interference color of the optical film so that the color of the film structure is substantially the same as the metal substrate.

Abstract: A coated article includes a substrate, an anti-corrosion layer formed on the substrate, and a decorative layer formed on the anti-corrosion layer. The substrate is made of aluminum or aluminum alloy. The anti-corrosion layer is an aluminum-copper alloy layer. The coated article has improved corrosion resistance.

Abstract: A bonding structure including: a ceramic member made of aluminum nitride and including a hole; a terminal embedded in the ceramic member, exposed to a bottom surface of the hole, and made of molybdenum; a brazed bond layer consisting of gold (Au) only; and a connecting member inserted in the hole, bonded to the terminal via the brazed bond layer, and made of molybdenum.

Abstract: The invention provides thin, hydrogen-permeable, sulfur-resistant membranes formed from palladium or palladium-alloy coatings on porous, ceramic or metal supports. Also disclosed are methods of making these membranes via sequential electroless plating techniques.

Abstract: Coated articles, electrodeposition baths, and related systems are described. The article may include a base material and a coating comprising silver formed thereon. In some embodiments, the coating comprises a silver-based alloy, such as a silver-tungsten alloy. The coating can exhibit desirable properties and characteristics such as durability (e.g., wear), hardness, corrosion resistance, and high conductivity, which may be beneficial, for example, in electrical and/or electronic applications. In some cases, the coating may be applied using an electrodeposition process.

Abstract: Method for chemical bonding of fiberglass fibers to steel surfaces to prepare the steel for bonding with carbon composite material. This fiber-bonding step greatly increases the strength of the subsequent metal-composite bond. The fiberglass fibers which are chemically bonded to the steel provide a high surface area interface to entangle with carbon fibers in the composite component, and thereby inhibit crack formation on the boundary surface between the steel and composite components when they are bonded together.

Abstract: Provided is a coated-surface sliding part having excellent adhesion of a hard coating, and a method for producing the same part. The coated-surface sliding part is a sliding part wherein a hard coating is formed by physical deposition on the surface of a base material formed from, by mass percent, C 0.5 to 0.8%, Si 0.1 to 1.5%, Mn 0.2 to 1.0%, Cr 8.0 to 13.5%, Mo and/or W 0.5 to 4.0% in terms of (Mo+ 1/2 W), and N 0.01 to 0.1%, with the remainder being Fe and impurities. The physically deposited coating is a titanium metal coating further covered by a diamond-like carbon coating. The method for producing a coated-surface part involves sputtering in order to apply the physically deposited coating, which consists of the titanium metal coating and then the diamond-like carbon coating which forms the surface layer, to the surface of the base material having the aforementioned composition. The base material is preferably subjected to argon gas bombardment prior to application of the physically deposited coating.

Abstract: A metallic solder rod is provided. The solder rod includes a stop-off at the end so that the solder cannot drip from an opening. The solder rod includes an inner region and an outer region which at least partially surrounds the inner region wherein the inner region includes a different alloy than the outer region. A process for applying solder to a hole in a substrate is also provided.

Abstract: Provided are a laminate for HDD suspension capable of avoiding data loss and crosstalk caused by higher frequency and coping with reduction in size and increase in capacity of HDD and a method for manufacturing the same. The laminate for HDD suspension comprises a 10-50 ?m-thick stainless steel layer, a 0.1-10 ?m-thick conductor layer (a) of a metal showing an electrical conductivity of 10-100% IACS, a 5-20 ?m-thick insulating layer of a polyimide resin showing a linear expansion coefficient of 1×10?5-3×10?5/° C., and a 5-50 ?m-thick conductor layer (b). The manufacturing method comprises applying a solution of a polyimide precursor in one layer or more to a conductor layer (a) of a laminate consisting of a stainless steel layer and a conductor layer (a), drying the polyimide precursor layer and then heating at 250° C. or above thereby forming a 5-20 ?m-thick insulating layer of polyimide resin with a linear expansion coefficient of 1×10?5-3×10?5/° C.

Abstract: A coated article includes a substrate, an anti-corrosion layer formed on the substrate, and a decorative layer formed on the anti-corrosion layer. The substrate is made of magnesium or magnesium alloy. The anti-corrosion layer is a magnesium layer. The coated article has improved corrosion resistance.

Abstract: A coated article includes a substrate, an anti-corrosion layer formed on the substrate and a decorative layer formed on the anti-corrosion layer. The substrate is made of aluminum or aluminum alloy. The anti-corrosion layer is an aluminum layer. The coated article has improved corrosion resistance.

Abstract: The invention relates to a coated article which has (i) at least one electrically non-conducting base layer, (ii) at least one layer of copper and/or a copper alloy, and (iii) a layer which contains at least one electrically conductive polymer, wherein the copper or copper alloy layer (ii) is positioned between the base layer (i) and the layer containing the conductive polymer (iii), and which is characterized in that the layer (iii) contains at least one precious metal or at least one semiprecious metal or a mixture thereof. The invention also relates to a process for its production and also its use for the prevention of corrosion and to preserve the solderability of printed circuit boards.

Abstract: A process for joining a brass part and a silicon carbide ceramic part comprising: providing a brass part, a SiC ceramic part, a Al foil and a Ni foil; placing the SiC ceramic part, the Al foil, the Ni foil, and the brass part into a mold, the Al foil and the Ni foil located between the SiC ceramic part and the brass part, the Al foil abutting against the SiC ceramic part, the Ni foil abutting against the brass part and the Al foil; placing the mold into a chamber of an hot press sintering device, heating the chamber and pressing the brass part, the SiC ceramic part, the Al foil, and the Ni foil at least until the brass part, the SiC ceramic part, the Al foil and the Ni foil form a integral composite article.

Abstract: A thermal conductivity substrate including a metal substrate, a metal layer, an insulating layer, a plurality of conductive structures, a first conductive layer and a second conductive layer is provided. The metal layer is disposed on the metal substrate and entirely covers the metal substrate. The insulating layer is disposed on the metal layer. The conductive structures are embedded in the insulating layer and connected to a portion of the metal layer. The first conductive layer is disposed on the insulating layer. The second conductive layer is disposed on the first conductive layer and the conductive structures. The second conductive layer is electrically connected to a portion of the metal layer through the conductive structures. The second conductive layer and the conductive structures are integrally formed.

Abstract: A gas turbine engine component (10) with an aluminide coating (42) on at least a portion of an airflow surface (18) that includes a roughening agent (44) effective to provide a desired surface roughness and a deposition process for forming such aluminide coatings (42). A layer (40) including a binder (38) and the roughening agent (44) maybe applied to the superalloy substrate (46) of the component (10) and the aluminide coating (42) formed on the airflow surface portion by exposing the component (10) and layer (40) to an appropriate deposition environment. Suitable roughening agents include metal and ceramic particles (44) that are dispersed on the airflow surface portion before exposure to the deposition environment. The particles (44), which are substantially intact after the aluminide coating (42) is formed, are dispersed in an effective number to supply the desired surface roughness.

Abstract: A coated article includes a substrate, a catalyst layer, a bonding layer and a hydrophobic layer. The catalyst layer made of tin is formed on the substrate. The bonding layer is formed on the catalyst layer, including titanium, tin, stannic oxide and titanium dioxide. The hydrophobic layer made of silicon-nitrogen is formed on the bonding layer.

Abstract: A coating includes a deposited layer. The deposited layer is a nickel-titanium carbonitride layer.

Abstract: A composite hard mask is disclosed that prevents build up of metal etch residue in a MRAM device during etch processes that define an MTJ shape. As a result, MTJ shape integrity is substantially improved. The hard mask has a lower non-magnetic spacer, a middle conductive layer, and an upper sacrificial dielectric layer. The non-magnetic spacer serves as an etch stop during a pattern transfer with fluorocarbon plasma through the conductive layer. A photoresist pattern is transferred through the dielectric layer with a first fluorocarbon etch. Then the photoresist is removed and a second fluorocarbon etch transfers the pattern through the conductive layer. The dielectric layer protects the top surface of the conductive layer during the second fluorocarbon etch and during a substantial portion of a third RIE step with a gas comprised of C, H, and O that transfers the pattern through the underlying MTJ layers.

Abstract: A process for joining a stainless steel part and a alumina ceramic part, comprising steps of: providing a metal part made of stainless steel, a ceramic part made of alumina ceramic, and a nickel foil; bring the metal part, ceramic part, and nickel foil into contact, with the nickel foil inserted between the metal part and ceramic part; applying a joining pressure of about 20˜60 MPa to the parts to be joined; and simultaneously applying a pulse electric current to the parts while the joining pressure is applied for heating up the parts to a joining temperature of about 950° C. to about 1150° C. at a rate of about 50˜300° C./min, maintaining the joining temperature for about 20˜40 minutes.

Abstract: An article, process, and method for surface plasmon resonance plates are described. A substrate is covered with a thin metal film onto which a second thin metal film is deposited. The surface of the second thin metal film is converted to the metal oxide which is used to covalently bond organosilanes to the surface. Reactive organosilanes containing terminal bonding groups are arranged in a plurality of spots that are surrounded by inert organosilanes. Biomolecule attachment to the binding group is detected or measured from surface plasmon signals from the first thin metal film.

Abstract: A magnesium alloy structural member includes a base material composed of a magnesium alloy having an aluminum content of 4.5% by mass to 11% by mass, in which the base material has a pair of first and second surfaces, the first surface and the second surface being opposite each other, in which when a distance between the first surface and the second surface is defined as a thickness and when surface area regions are defined as regions extending from the first and second surfaces to positions 20 ?m from the respective first and second surfaces in the thickness direction, in at least both the surface area regions, 10 or more fine precipitates are present in any 20 ?m×20 ?m subregion of each of the surface area regions, each of the fine precipitates containing both Mg and Al and having a greatest dimension of 0.5 ?m to 3 ?m.

Abstract: [Object] To provide a metal-coated polyimide resin substrate that does not deteriorate the initial adhesion between the metal-coated polyimide resin film and the metal layer and has high adhesion after aging at 150° C. for 168 hours. [Solution] A metal-coated polyimide resin substrate in which a barrier layer is formed by a wet process after performing surface modification to one surface or both surfaces of a polyimide resin film by a wet process or a dry process or a combination thereof, a seed layer is thereafter formed by a wet process or a dry process, and a conductive film is formed on a surface layer thereof by a wet process; wherein, at the peeling surface on the conductive film layer side after the metal-coated polyimide resin substrate is subject to a 90-degree peel test, the thickness of a mixed layer of polyimide residue and barrier metal layer residue according to in-depth profiling with a time-of-flight secondary ion mass spectrometer (TOF-SIMS) is 2.

Abstract: A Clad material superimposed aluminum materials on stainless steel materials forms coating film by the electrodeposition coating on each whole surface of stainless steel material and aluminum material. A film of the aluminum material is removed by the irradiation of the laser beam, and the aluminum material of this region is exposed. Aluminum material is introduced into an injection molding machine after forming anodizing film. The synthetic resin part is formed with invading a synthetic resin to aperture of anodizing film. Then the composite component of clad material and synthetic resin part is produced.

Abstract: A protective coating system for metal components includes a superalloy metal substrate, such as a component of a gas turbine. A single layer bond coat is applied to the superalloy metal substrate in a thermal spray process from a homogeneous powder composition having a particle size distribution wherein about 90% of the particles by volume are within a range of about 10 ?m to about 100 ?m. The percentage of particles within any 10 ?m band within the range does not exceed about 20% by volume, and the percentage of particles within any two adjacent 10 ?m bands within the range does not deviate by more than about 8% by volume.

Abstract: A surface hardened substrate includes a base, a transition layer disposed on a surface of the base, and a hard layer disposed on the transition layer. The transition layer includes at least two kinds of transition metals. The hard layer includes an alloy and a nonmetal. The alloy includes the at least two kinds of transition metals.

Abstract: A surface hardened substrate includes a base, a transition layer disposed on a surface of the base, and a hard layer disposed on the transition layer. The transition layer includes at least two kinds of transition metals. The hard layer includes a composite that comprises the at least two kinds of transition metals and a nonmetal.

Abstract: A combustion turbine component (10) includes a combustion turbine component substrate (16) and an alloy coating (14) on the combustion turbine component substrate. The alloy coating (14) includes nickel (Ni), chromium (Cr), aluminum (Al), and yttrium (Y). Furthermore, the alloy coating includes at least one of titanium (Ti), tantalum (Ta), tungsten (W), and rhenium (Re). The alloy coating also includes at least one rare earth element, and an oxide of at least one of the yttrium (Y) and the at least one rare earth element.

Abstract: A combustion turbine component (10) includes a combustion turbine component substrate (16) and an alloy coating (14) on the combustion turbine component substrate. The alloy coating (14) includes a first amount, by weight percent, of cobalt (Co) and a second amount, by weight percent, of nickel (Ni), the first amount being greater than the second amount. The alloy coating further includes chromium (Cr), aluminum (Al), at least one rare earth element, and an oxide of the at least one rare earth element.

Abstract: A combustion turbine component (10) includes a combustion turbine component substrate (16) and an alloy coating (14) on the combustion turbine component substrate. The alloy coating (14) includes a first amount, by weight percent, of nickel (Ni) and a second amount, by weight percent, of cobalt (Co), the first amount being greater than the second amount. The alloy coating also includes chromium (Cr), aluminum (Al), and yttrium (Y). The alloy coating further includes at least one of titanium (Ti), tantalum (Ta), tungsten (W), and rhenium (Re). Moreover, the alloy coating includes at least one rare earth element, and an oxide of at least one of the yttrium the at least one rare earth element.

Abstract: A method for manufacturing a superconducting wire includes the following steps. A laminate metal having a first metal layer and a Ni layer formed on the first metal layer is prepared. An intermediate layer is formed on the Ni layer of the laminate metal. A superconducting layer is formed on the intermediate layer. By subjecting the laminate metal to a heat treatment after at least either of the step of forming a intermediate layer and the step of forming a superconducting layer, a nonmagnetic Ni alloy layer is formed from the laminate metal.

Abstract: A surface piece of crossing threads (12, 14) comprising plastic filaments, which as a woven fabric web (10) is equipped with two mutually opposing surfaces and with openings (16) formed therein. The fabric web comprises a metallisation applied on one side as a surface layer and between 15 and 80%, in particular between 20 and 70% of the fabric web is configured in the form of network intermediate spaces (16).