Abstract: A method of forming a sputtering target assembly and the sputtering target assembly made therefrom are described. The method includes bonding a sputtering target to a backing plate at a low temperature. Also described is a method of forming a sputtering target assembly such that a gap is formed between the sputtering target and the backing plate. Also described is a method of forming a sputtering target assembly providing a mechanism to prevent unintended sputtering into the backing plate.

Abstract: A method for producing a bonded body of different materials of the present invention is a method for producing a bonded body of different materials (1), where two plate members (2 and 3) are bonded to each other, the method including: laminating two plate members (2 and 3) consisting of different materials to obtain a plate-member-laminated-body (4), and heating the plate-member-laminated-body (4). The method includes a step of heating the plate-member-laminated-body (4) while it is sandwiched between a pair of pressing dies (5). The pressing die (5) is made of a material having a heat transfer coefficient 1.5 times or more higher than that of at least one of the plate members (2 and 3) constituting the plate-member-laminated-body (4) and has a tapered part (6) between holding surface (15) which hold the plate-member-laminated-body (4) and a fixing end (16) for securing the pressing die (5). The outer diameter of the tapered part is reduced from the holding surface (15) toward the fixing end (16).

Abstract: An electric contact for high-temperature fuel cells and to methods for the production of said contacts. The aim of the invention is to enable long-term use at high operating temperatures of up to 950° C., offering high electrical conductivity and being able to be produced at low cost. The inventive electric contact is produced from a composite consisting of a metal component and a ceramic component. The metal component is, preferably, formed with at least one metal oxide.

Abstract: A method for utilizing superplastic deformation with or without a novel joint compound that leads to the joining of advanced ceramic materials, intermetallics, and cermets. A joint formed by this approach is as strong as or stronger than the materials joined. The method does not require elaborate surface preparation or application techniques.

Abstract: A heat pipe housing assembly (22) includes a pair of silicon housing pieces (24, 26) and a bond joint (42) between the housings (24, 26), with the bond joint (42) preferably including a eutectic layer (43).

Abstract: A method for welding to a superalloy material without causing cracking of the material. The method includes the steps of depositing a weld strip (18) of a weldable material onto a superalloy substrate material (12) using a spray deposition process (20) and then forming a weldment (26) to the weld strip. None or a controlled amount of the substrate material (12) is melted during the weld in order to maintain the concentration of strengthening elements in the local melt within a zone of weldability. The spray deposition process may be a thermal process such as HVOF or a cold spray process. A groove (16) may be formed in a surface (10) of the superalloy substrate material to receive the weld strip. A diffusion heat treatment step may be used to improve adhesion between the weld strip and the superalloy material.

Abstract: A combinatorial process for production of material libraries from a single sample, comprising forming a diffusion multiple in the single sample, wherein the diffusion multiple comprises a plurality of interdiffusion regions at interfacial locations of dissimilar metals, metal oxides, or alloys, and wherein the diffusion multiple comprises at least three layers of the metals, non-metals, metal oxides, or alloys; and evaluating properties of the diffusion multiple as a function of composition at about the interdiffusion regions.

Abstract: Thermally stable ultra-hard compact constructions comprise a polycrystalline diamond body substantially free of a catalyst material, and a substrate that is joined thereto. The substrate can be ceramic, metallic, cermet and combinations thereof, and can be joined to the body by a braze material or other material that forms an attachment bond at high pressure/high temperature conditions. The body and substrate are specially formed having complementary interfacing surface features to facilitate providing an improved degree of attachment therebetween. The complementary surface features can in the form of openings and projections, e.g., one of the body or substrate can comprise one or more openings, and the other of the body or substrate can comprise one or more projections, disposed within or extending from respective interfacing surfaces. The complementary surface features operate to resist unwanted delamination between the body and substrate, thereby extending effective service life of the construction.

Abstract: A method of repairing a metal component comprising depositing a nanoparticle alloy within a crack of the metal component, depositing a filler alloy over the deposited nanoparticle alloy, and diffusion brazing the metal component.

Abstract: A method for joining microstructured component layers and a method for manufacturing microstructure component layers and the microstructure component layer is provided. At least one multifunctional barrier coating is applied to the joining surfaces of a base material layer for the microstructured component layers. The layers are made of aluminum/aluminum alloys and/or copper/copper alloys, and/or noble steels. At least one solder/brazing coating is applied to each barrier coating. The coated base material layers comprising the component layers are stacked. The stacked component layers are joined by solder/brazing using heat. The melting temperature of the solder/brazing coating is higher after the heat joining than before same.

Abstract: According to one aspect of the invention it is possible to rapidly heat a soldering item by reducing an initially larger volume flow at a constant or increasing temperature, effectively preventing small components from overheating. By using the volume flow of a convection heater to control effective heat transmission occurring on said soldering item, it is also possible to adapt the soldering process in an extremely flexible manner to special process requirements by virtue of the fact that adjustment of a modified volume flow can be controlled in a very quick and precise manner.

Abstract: A novel method for bonding components has been disclosed. For bonding ceramic components the method involves placing at least three metal interlayers between the components. There is a central core metal layer and two other metal layers placed on either side of the core layer adjacent the ceramic components. The metal layers are heated to a temperature sufficient to transform at least part of the metal layers into a liquid. The temperature is maintained until the liquid begins to solidify and the first points of bonding between the components and the solidifying interlayer is established. This system can also be used to bond a ceramic component to a metal component. The metal component can be placed adjacent the central core metal layer without an intervening metal layer.

Abstract: Method for assembling at least two pieces of silicon carbide based materials by non reactive refractory brazing, wherein these pieces are put into contact with a non reactive brazing solder composition and the assembly formed by the pieces and the brazing solder composition is heated to a brazing temperature sufficient to fuse the brazing solder composition in order to form a refractory joint, in which the non reactive brazing solder composition is constituted, in atomic percentages, of from 40 to 97% silicon and of from 60 to 3% of another element chosen in the group consisting of chromium, rhenium, vanadium, ruthenium, iridium, rhodium, palladium, cobalt, platinum, cerium and zirconium and wherein, before brazing, a strengthening agent of SiC and/or C is added. Brazing solder composition, composition for refractory brazing. Refractory joint and assembly obtained by the method.

Abstract: The invention relates to a process for the metallization with a silicon alloy melting at a temperature T1 of certain zones of the surface of a part made of an oxide ceramic unable to be wetted by the said alloy, the said process comprising, in succession, a step of depositing carbon on the said zones of the said part that are to be metallized, a step of depositing the silicon alloy in solid form on at least one portion of the said part, so that the said alloy has at least one point of contact with the said zones to be metallized, followed by a heating step at a temperature greater than or equal to T1, the said alloy gathering in the molten state on the said zones to be metallized. This process applies also to the brazing of parts, at least one of which is a part made of an oxide ceramic unable to be wetted by the said alloy. Application of the said processes to the fields of electronics, electrical engineering, thermal engineering and chemical engineering.

Abstract: A joint having bond line grains that nucleate in the joint region and grow into the adjoined solid substrates. The resulting bond line grains have a size that is greater than a thickness of a molten region. The surfaces of the substrates are cold worked to a desired degree of residual stress prior to the bonding process so that the recrystallization of the substrate surface necessary for the grains to grow into the substrates results in a reduction in the local free energy.

Abstract: Methods of bonding two components may include positioning the components relative to one another to obtain a desired orientation. Once the desired orientation is obtained, the components can be bonded in the desired orientation with metal wherein a temperature of both components is maintained below a melting temperature of the metal while bonding. Related structures are also discussed.

Abstract: A weld nugget between aluminum alloy parts is inoculated with a material in order to refine the grain structure of the weld and thereby improve its mechanical strength. The inoculate may be a Ti or Na based compound in the form of a paste, powder or film, which is applied to the sheets before welding. The inoculation promotes nucleation of desirable equiaxed grain within the molten weld nugget as the weld cools and solidifies.

Abstract: A method for producing permanent integral connections of oxide-dispersed metallic materials by welding. The materials or components to be connected are overlapped to form an overlapping region in a joining region of the overlapping region. The materials or components are heated below the melting temperatures of the materials and are welded to at least partially form a diffusion bond by a welding method. A noble metal foil may be between the components to be connected. The diffusion bond is heated subsequently to a temperature below the melting temperature of the materials or components and the bond is mechanically recompacted by hammering.

Abstract: A microchannel plate (MCP) (50) and a dielectric insulator (80) are deposited with a thin film (54, 84) using a suitable metal selected for optimum diffusion. The metallized MCP (50) and dielectric insulator (80) are then aligned and placed in a bonding fixture (36) that provides the necessary force applied to the components to initiate a diffusion bond. The bonding fixture (36) is then placed in a vacuum heat chamber to accelerate the diffusion bonding process between the MCP (50) and the dielectric insulator (80).

Abstract: A method for producing a plate heat exchanger with multiple plates made of a solderable material. The plated define circuits for fluid circulation and are assembled together by soldering. The soldering is done after a soldering material is applied to the regions to be soldered. The soldering material is deposited on the plates with an electrolytic solution.

Abstract: Methods for making abrasive water jet mixing tubes with superhard materials are presented. Also presented are methods for making a tubular elongate superhard material bodies.

Abstract: A method of diffusion welding of different metals is accomplished while applying pressure to the butt area and homogeneous heating the butt area to about 0.8 to about 0.9 the melting point of the metals to be welded. Additional heat pulses are then supplied to the butt area. The number of additional heat pulses depends on the diameter of the pieces to be welded. The heat pulses provide for a more even temperature distribution over the butt area and increases the number of active diffusion centers to enhance the diffusion process. The method is useful for different refractory and stainless steels and alloys. The resultant diffusion welds do not produce burring.

Abstract: A method of joining superalloy substrates together comprises diffusion bonding the superalloy substrates by depositing an activator directly on the surface of the joint to be bonded and thereafter subjecting the joint to heat and pressure. The heat and pressure causes the surface of the superalloy, in the presence of the activator, to diffusion bond without the use of a brazing alloy. By eliminating the brazing alloy, a high strength, high temperature bond is achieved, yet there is no molten brazing alloy to be drawn through capillary action into any fine features surrounding the joint being bonded, and there is no residue left at the interface that would diminish the mechanical or chemical properties of the joint.

Abstract: The invention discloses a microelectroforming mold using a preformed metal as the substrate and its fabrication method. Using a preformed metal as the substrate can avoid deformation of the microelectroforming mold due to residual stress in the electroforming metal. The fabrication method disclosed herein includes the steps of: forming a layer of bonding material on a surface of the preformed metal substrate after machining; forming a high aspect ratio photoresist microstructure on surfaces of the metal substrate and the bonding material; putting an electroforming material into the gaps of the photoresist microstructure to form an electroforming metal microstructure; and using a thermal process to bond the metal substrate and the metal micro structure by the bonding material and simultaneously bum off the photoresist microstructure to form a micro-electroforming mold.

Abstract: Methods of bonding two components may include positioning the components relative to one another to obtain a desired orientation. Once the desired orientation is obtained, the components can be bonded in the desired orientation with metal wherein a temperature of both components is maintained below a melting temperature of the metal while bonding. Related structures are also discussed.

Abstract: Systems and methods for forming a seal between members of an assembly are disclosed. In one embodiment, a seal is formed between a first member and a second member by establishing within the members a bounded volume and creating within the bounded volume a pressure differential with respect to the ambient pressure outside the bounded volume. The pressure differential results in a uniformly applied clamping force to the members thereby creating a reliable seal. A sealing member (such as solder, epoxy, or other sealant) is positioned between the first and second members and the resulting assembly is mechanically positioned such that heat can then be applied to melt the solder. Concurrently, the pressure differential is created which allows the externally applied mechanical positioning to be relaxed while the members are being sealed together. This system and method can be used to create hermetic seals.

Abstract: A backing plate of Ti for supporting a Ti sputtering target is formed of at least two components welded together. The backing plate is welded by interposing a Cu or Zr foil or powder between faces to be welded, and then heating the assembly to a reaction temperature high enough to melt one of the Ti and Cu or Zr to produce a liquid phase. The heating temperature is retained for a time long enough to permit diffusion of the Cu or Zr into the Ti to produce a liquid phase diffusion weld. By permitting diffusion to occur, a separate metallic compound is not produced at the welding face. In effect welding is accomplished without producing a welding face, whereby no interface exists in the finished weld. The resulting weld has a strength substantially equal to the strength of the Ti material, and very good welding qualities.

Abstract: A highly heat-resistant laminated component for a fusion reactor has at least of a plasma-facing area made of tungsten or a tungsten alloy, a heat-dissipating area of copper or a copper alloy with a mean grain size of more than 100 &mgr;m, and an interlayer of a refractory metal-copper-composite. The refractory metal-copper-composite has a macroscopically uniform copper and refractory-metal concentration progression and a refractory metal concentration of between 10 vol. % and 40 vol. % over its entire thickness.

Abstract: Mating faces of a microchannel plate (MCP) (50) and a multi-layer ceramic body (80) unit are deposited with a thin film having protuberances (84) using a suitable metal selected for optimum diffusion at a desired temperatures and pressure. The metallized MCP (50) and multi-layer ceramic body (80) unit are then aligned and placed in a bonding fixture (F) that provides the necessary force applied to the components to initiate a diffusion bond at a desired elevated temperature. The bonding fixture (F) is then placed in a vacuum heat chamber (V) to accelerate the diffusion bonding process between the MCP (50) and the multi-layer ceramic body unit (80).

Abstract: The present invention relates to a diffusion bonding target assembly of a high purity cobalt target and a copper alloy backing plate diffusion bonded with an aluminum or aluminum alloy having a thickness of 0.5 mm or more as the insert material. Provided is a diffusion bonding target assembly of a high-purity cobalt target and a copper alloy backing plate capable of effectively sputtering a high purity cobalt ferromagnetic target and which does not generate warping or peeling upon diffusion bonding even under severe conditions such as bonding with the backing plate and high power sputtering, and the manufacturing method thereof.

Abstract: A method of joining superalloy substrates together comprises diffusion bonding the superalloy substrates by depositing an activator directly on the surface of the joint to be bonded and thereafter subjecting the joint to heat and pressure. The heat and pressure causes the surface of the superalloy, in the presence of the activator, to diffusion bond without the use of a brazing alloy. By eliminating the brazing alloy, a high strength, high temperature bond is achieved, yet there is no molten brazing alloy to be drawn through capillary action into any fine features surrounding the joint being bonded, and there is no residue left at the interface that would diminish the mechanical or chemical properties of the joint.

Abstract: Methods of bonding two components may include positioning the components relative to one another to obtain a desired orientation. Once the desired orientation is obtained, the components can be bonded in the desired orientation with metal wherein a temperature of both components is maintained below a melting temperature of the metal while bonding. Related structures are also discussed.

Abstract: The invention provides metal connecting composition for connecting metal to metal with removing oxide film on the mother metal surface. The metal connecting composition contains metal particles and hydrocarbon compound having C—H bonding dissociation energy of a value equal to or lower than 950 KJ/mol. When metal pieces between which the metal connecting composition is applied is heated, the hydrocarbon compound is dehydrogenated to form radical, and the radical reduces oxide film on the metal surface to be connected.

Abstract: The invention includes an assembly (130) having a physical vapor deposition target (102) separated from a backing plate (120) with a layer (104) consisting essentially of one or both of molybdenum and tantalum. The invention also includes an assembly comprising a backing plate of at least 99.9% aluminum bound to a target of at least 99.9% molybdenum through a bond having a strength of at least about 6,000 pounds per square inch (psi). Additionally, the invention includes a method of bonding a tungsten-containing material to an aluminum-containing material. A layer of molybdenum-containing material (104) is provided between the tungsten-containing material (102) and the aluminum-containing material (120); and is bonded to both the tungsten-containing material (102) and the aluminum-containing material (120).

Abstract: A tantalum or tungsten target-backing plate assembly which comprises a tantalum or tungsten target and a copper alloy backing plate that are subject to diffusion bonding via an aluminum- or aluminum alloy-sheet insert material at least 0.5 mm thick, and which is provided with diffusion bonded interfaces between the respective materials, wherein the assembly suffers only a small deformation after diffusion bonding and is free from separation between the target and the backing plate or from cracking even when the target material and the backing plate differ greatly in thermal expansion, and can survive high power sputtering; and a production method therefor.

Abstract: A sputtering target is provided, including a target material and a backing plate that are bonded with a strong adhesion at a reduced cost. The method for bonding the target material and the backing plate does not use a special soldering material, and is therefore cheaper and more reliable. The target includes an inorganic target material and a backing plate that are bonded with a soldering material between them. At least one of the target material and the backing plate is coated with a coupling agent of a semi-metal oxide or a metal oxide.

Abstract: A method for making a joint between copper or copper alloys and austenitic steel alloys, in which method in between the junction surfaces of the objects to be joined together, there is arranged at least one intermediate layer, so that the junction surfaces, including their intermediate layers, are pressed together, and at least the junction area is heated in order to create a diffusion joint. In the method, there is brought a first intermediate layer (3) on the junction surface of the steel object (2) or against said surface, in order to activate the creation of the diffusion joint.

Abstract: A backing plate of Ti for supporting a Ti sputtering target is formed of at least two components welded together. The backing plate is welded by interposing a Cu or Zr foil or powder between faces to be welded, and then heating the assembly to a reaction temperature high enough to melt one of the Ti and Cu or Zr to produce a liquid phase. The heating temperature is retained for a time long enough to permit diffusion of the Cu or Zr into the Ti to produce a liquid phase diffusion weld. By permitting diffusion to occur, a separate metallic compound is not produced at the welding face. In effect welding is accomplished without producing a welding face, whereby no interface exists in the finished weld. The resulting weld has a strength substantially equal to the strength of the Ti material, and very good welding qualities.

Abstract: Known manufacturing methods for microstructure components, in particular for microreactors, micro-heat exchangers, and micromixers, are not reliable enough to ensure that the component's pressure and corrosion resistance is high enough, that the component's tightness against fluid exiting from the component or fluid spilling over into adjacent microchannels is high enough, and that the microchannels have a sufficiently low flow resistance. In addition, known manufacturing methods are not cost-effective enough that the microstructured components can be employed in a wide variety of applications.

Abstract: A titanium target assembly includes a titanium sputtering target, a copper or copper alloy backing plate and serving as a support member for the target and a silver or silver alloy coating film and formed between the target and backing plate. The coating film is formed on a surface subjected to cleaning treatment on the bonding side or sides of the target and backing plate by physical vapor deposition. The titanium target and backing plate are solid phase diffusion bonded. The face(s) serve as the bonding plane. The assembly can be manufactured by cleaning the surface(s) of the target and/or backing plate on bonding side(s), forming a coating film on the cleaned surface(s) on bonding side(s) and solid phase diffusion-bonding the target and backing plate, while using surface(s) provided with coated film as the bonding plane. The target assembly possesses high bonding strength and excellent bonding stability and reliability.

Abstract: A liquid interface diffusion bonded composition comprises a metal honeycomb core such as a nickel-alloy honeycomb core and a nickel-alloy facing sheet bonded thereto. The composition and method of this invention are useful in applications where high strength, heat resistant materials are required, such as in aircraft and aerospace-related structures.

Abstract: A method of joining surfaces comprising: providing a first surface comprising a layer of silver; interposing between the first surface and a second surface a eutectic composite which melts below 140° C.; raising the temperature of the eutectic composite to a first temperature above the eutectic temperature to at least partially melt the eutectic composite and form molten eutectic alloy; and contacting the molten eutectic alloy with silver layer of the first surface so as to cause inter-diffusion and reaction between the eutectic alloy and the silver, wherein the relative proportions of silver and eutectic composite are selected such that a non-eutectic composition forms between silver and the metals contained in the eutectic composite, the non-eutectic composition having a melting temperature higher than said first temperature.

Abstract: A method for producing diffusion bonds between components formed of tungsten heavy alloy (WHA) uses aid material to accelerate diffusion across the joint surfaces. The aid material consists of an alloy of palladium (Pd) with one or more of the secondary elements of nickel (Ni), iron (Fe), or cobalt (Co). The secondary elements are selected to correspond to the secondary elements present in the components. The diffusion bonding is carried out by placing diffusion aid material between the joint surfaces of adjacent components, applying a pressure across the joint surfaces, and processing the assembly through a thermal profile. Structures of WHA with complex shapes, interior volumes and/or large sizes can be formed. The joint properties are equal to or superior to those of the parent material of the components.

Abstract: A braze material (10) including nano-sized filler material particles (14). The nano-sized particles will melt at a temperature significantly lower than the micron-sized particles used in prior art braze materials, thereby eliminating or reducing the need for the addition of temperature depressant materials such as boron or silicon. The resulting braze joint is substantially free of detrimental boride and suicides phases, thereby improving the material properties of the joint, eliminating the need for a separate post-braze diffusion heat treatment, and permitting a subsequent welding operation with reduced risk of cracking. The braze heat treatment may also function as a solution heat treatment, a pre-weld heat treatment or a post-weld heat treatment.

Abstract: A method and an apparatus incorporating the method for making a long, continuous laminate. A plurality of layers of materials are simultaneously wound around a metal hub. Strips of refractory material, perforated metal, metal foil, metal mesh, and random fiber media, are employed in the layers of materials. The hub, once completed, is placed into a furnace for diffusion bonding and later cooled to room temperature. The cooled laminate coil may be cut into various lengths.

Abstract: The aim of the present invention is a process for manufacturing a plated product (1) comprising a support part in steel (2) and an anticorrosion metallic coating (3), characterized in that the anticorrosion coating (3) is fixed on the support part (2) by controlled-atmosphere brazing, in particular by vacuum brazing. The process according to the invention makes it possible to fix solidly an anticorrosion coating with a thickness smaller than 1 mm on a steel plate.

Abstract: The invention includes an aluminum-comprising physical vapor deposition target bonded to an aluminum-comprising backing plate to a bond strength of greater than 10,000 pounds/in2. The invention also includes a method of bonding a first aluminum-comprising mass to a second aluminum-comprising mass. The first aluminum-comprising mass has a first surface, and the second aluminum-comprising mass has a second surface. The first and second masses are pressed together to bond the first mass to the second mass. Additionally, the invention includes a method of bonding a physical vapor deposition target material to a backing plate material. The target material and backing plate material are joined in physical contact with one another. The target material and backing plate material are then compressed under a load that progresses sequentially.

Abstract: A preferred sputter target assembly (10, 10′) comprises a target (12, 12′), a backing plate (14, 14′) bonded to the target (12, 12′) along an interface (22, 22′) and dielectric particles (20, 20′) between the target (12, 12′) and the backing plate (14, 14′). A preferred method for manufacturing the sputter target assembly (10, 10′) comprises the steps of providing the target (12, 12′) and the backing plate (14, 14′); distributing the dielectric particles (20, 20′) between mating surfaces (24, 26) of the target (12, 12′) and the backing plate (14, 14′), most preferably along a sputtering track pattern on one of the mating surfaces; and bonding the target (12, 12′) to the backing plate (14, 14′) along the mating surfaces (24, 26).

Abstract: A first member 10 containing at least ceramics and a second member 12 containing at least a metal or a metal composite was joined with each other. An adhesive 2 composed of a metal containing at least indium and materials 1A, 1B containing at least a component capable of reducing the melting point of indium between the first and second members to provide a laminate 13. The laminate 13 is heated at a temperature in solid-liquid coexisting range of an alloy comprising indium and said component to join the first member 10 and second member 12.

Abstract: Deterioration and damage to insulator materials in an interconnection structure having vertical connections due to exposure to heat during bonding of lamina is avoided by performing diffusion bonding of metal pads at plated through holes (PTH) at temperatures below the melting points of conductive material in the bond. Diffusion bonding is achieved during time periods required for processing (e.g. curing or drying) of insulating materials in the laminated structure.