Abstract: A structure which is resistant to corrosion at high temperatures comprises a layer of ruthenium and/or ruthenium alloy and a layer of a refractory metal having a high strength at high temperatures, such as rhenium. Further, the structure may include a layer of ceramic such as zirconia or hafnia on the exposed face of the ruthenium layer. Alternative embodiments of the present invention include a catalyst formed from a low strength support structure with a first metal layer and a second ruthenium catalytic layer on top of the first metal layer. Another alternative embodiment of the present invention includes the formation of high purity ruthenium electrodes that are resistant to corrosion at high temperatures.

Abstract: This invention provides an electrolyte salt for use in an electrodeposition process for depositing Zirconium metal on a thin foil substrate. The prior art electrochemical process causes a reaction between a uranium substrate and ZrF4 species in the electrolyte that causes the formation of UFx at the substrate surface that prevents the formation of a dense uniform zirconium coating. This problem is solved by using an electrolyte salt in an electrodeposition process consisting of lithium fluoride (LiF) in a concentration ranging between about 11.5 molar percent and about 61 molar percent and one or more salts selected from the group consisting of sodium fluoride (NaF), potassium fluoride (KF), cesium fluoride (CsF), or cesium chloride (CsCL). Zirconium is added to the electrolyte salt through an addition of zirconium fluoride (ZrF4) in the range of about 1 to about 5 mass percent (w/w %). The Zr coating is of at least 98% pure Zr with a density of at least 98%.

Abstract: A method for fabricating and the resulting x-ray target comprising metal deposited on an electrically-conductive base member by electrodeposition from a molten salt electrolyte is claimed. The method comprises submerging the base member in a molten salt electrolyte bath. The base member acts as a cathode and anodes of target material metals are activated by electrical circuitry to deposit a target layer onto the base member. The electrodeposition method results in an exceptionally dense and pure layer of tungsten or tungsten alloy. Target materials of tungsten, tungsten alloy, rhenium, and rhenium alloy produce good results when electrodeposited onto base members fabricated from molybdenum, molybdenum alloy, and graphite-or carbon-based composites.

Abstract: A melting tank for melting solder glass powders typically comprised of PbO and B2O3 and other minor ingredients. The tank contains surfaces exposed to the atmosphere and surfaces in contact with the molten solder glass. The surfaces of the tank that are in contact with the melt are comprised substantially entirely of iridium. Preferably, the surfaces exposed to the atmosphere contain a coating thereon of a metal or metal oxide such as palladium, ruthenium, rhodium, aluminum oxide, calcium oxide, cerium dioxide, dichromium oxide, hafnium dioxide, magnesium oxide, silicon dioxide, thorium dioxide, zirconia, mullite, magnesia spinel or zircon. It is also preferred that the cavity of the tank have a generally circular shape. The melting tank may be readily fabricated by wrought metallurgical processes or by electroforming.