An Ag alloy sputtering target of the present invention includes, as a composition, 0.1 at % to 3.0 at % of Sn, 1.0 at % to 10.0 at % of Cu, and a balance of Ag and inevitable impurities. In addition, an Ag alloy film of the present invention includes, as a composition, 0.1 at % to 3.0 at % of Sn, 1.0 at % to 10.0 at % of Cu, and a balance of Ag and inevitable impurities.

The present invention relates to a method for producing a platinum-based alloy powder, the method comprising a heat treatment of a mixed powder containing a platinum-based powder composed of at least one selected from the group consisting of platinum and platinum compound, a platinum group metal-based powder composed of at least one selected from the group consisting of iridium, rhodium, palladium, and compound containing at least one of them, and an alkaline-earth metal compound, wherein specific surface area of the platinum group metal-based powder is 30 m.sup.2/g or more and D90 of the mixed powder is 1.0 μm or less. According to the method for producing a platinum-based alloy powder of the invention, it is possible to produce a platinum-based alloy powder that has a desired particle diameter, also has a sharp particle size distribution, and has high purity and crystallinity.

The present invention relates to a method for producing a platinum-based alloy powder, the method comprising a heat treatment of a mixed powder containing a platinum-based powder composed of at least one selected from the group consisting of platinum and platinum compound, a platinum group metal-based powder composed of at least one selected from the group consisting of iridium, rhodium, palladium, and compound containing at least one of them, and an alkaline-earth metal compound, wherein specific surface area of the platinum group metal-based powder is 30 m.sup.2/g or more and D90 of the mixed powder is 1.0 μm or less. According to the method for producing a platinum-based alloy powder of the invention, it is possible to produce a platinum-based alloy powder that has a desired particle diameter, also has a sharp particle size distribution, and has high purity and crystallinity.

The present invention relates to a medical Au—Pt—Pd alloy including Au, Pt, Pd, and inevitable impurities. The alloy has an alloy composition inside a polygon (A1-A2-A3-A4-A5-A6) surrounded by straight lines connected at point A1 (Au: 37.9 atom %, Pt: 0.1 atom %, and Pd: 62 atom %), point A2 (Au: 79.9 atom %, Pt: 0.1 atom %, and Pd: 20 atom %), point A3 (Au: 79.9 atom %, Pt: 20 atom %, and Pd: 0.1 atom %), point A4 (Au: 69.9 atom %, Pt: 30 atom %, and Pd: 0.1 atom %), point A5 (Au: 49 atom %, Pt: 30 atom %, and Pd: 21 atom %), and point A6 (Au: 39 atom %, Pt: 40 atom %, and Pd: 21 atom %) in a Au—Pt—Pd ternary state diagram. The metal structure of the alloy is optimized, and the metal structure is close to a single-phase structure, and has little precipitation of a Au-rich phase and a Pt-rich phase different in composition from a mother phase.

The present invention includes composition and methods for the fabrication of very-high-aspect-ratio structures from metallic glasses. The present invention provides a method for nondestructive demolding of templates after thermoplastic molding of metallic glass features.

The present invention includes composition and methods for the fabrication of very-high-aspect-ratio structures from metallic glasses. The present invention provides a method for nondestructive demolding of templates after thermoplastic molding of metallic glass features.

A plasmonic scattering nanomaterial comprising a substrate layer, a metal oxide layer in continuous contact with the substrate layer and silver nanoparticles with a diameter of 25-300 nm deposited on the metal oxide layer is disclosed. The silver nanoparticles have a broad size distribution and interparticle distances such that the silver nanoparticles plasmonically scatter light throughout the metal oxide layer with a near electric field strength of 1-30 V/m when excited by a light source having a wavelength in the range of 300-500 nm and/or 1000-1200 nm. In addition, a method for producing the nanomaterial by sputter deposition is disclosed as well as an appropriate thin film plasmonic solar cell comprising the nanomaterial with a solar efficiency of at least 10%.

A plasmonic scattering nanomaterial comprising a substrate layer, a metal oxide layer in continuous contact with the substrate layer and silver nanoparticles with a diameter of 25-300 nm deposited on the metal oxide layer is disclosed. The silver nanoparticles have a broad size distribution and interparticle distances such that the silver nanoparticles plasmonically scatter light throughout the metal oxide layer with a near electric field strength of 1-30 V/m when excited by a light source having a wavelength in the range of 300-500 nm and/or 1000-1200 nm. In addition, a method for producing the nanomaterial by sputter deposition is disclosed as well as an appropriate thin film plasmonic solar cell comprising the nanomaterial with a solar efficiency of at least 10%.

A structure of assembly grasp for palladium-alloy tubes and the manufacturing method thereof are described. The structure of assembly grasp for palladium-alloy tubes includes a grasp with a plurality of holes, a plurality of palladium-alloy tubes inserted into the plurality of holes, and an intermetallic compound layer between the palladium-alloy tubes and the inner sidewalls of the plurality of holes.

A structure of assembly grasp for palladium-alloy tubes and the manufacturing method thereof are described. The structure of assembly grasp for palladium-alloy tubes includes a grasp with a plurality of holes, a plurality of palladium-alloy tubes inserted into the plurality of holes, and an intermetallic compound layer between the palladium-alloy tubes and the inner sidewalls of the plurality of holes.