Metallic matrix composites include a high strength titanium aluminide alloy matrix and an in situ formed aluminum oxide reinforcement. The atomic percentage of aluminum in the titanium aluminide alloy matrix can vary from 40% to 48%. Included are methods of making the metallic matrix composites, in particular, through the performance of an exothermic chemical reaction. The metallic matrix composites can exhibit low porosity.

The cathode member for electron beam generation of the present disclosure includes: 95% by area or more of a single phase or two phases of a compound composed of iridium and cerium. A total content of one or more subcomponents of metallic iridium and an oxide of one or more elements of iridium and cerium is 5% by area or less of the cathode member.

An additive manufacturing method of producing a metal alloy article may involve: Providing a supply of a metal alloy in powder form; providing a supply of a nucleant material, the nucleant material lowering the nucleation energy required to crystallize the metal alloy; blending the supply of metal alloy powder and nucleant material to form a blended mixture; forming the blended mixture into a first layer; subjecting at least a portion of the first layer to energy sufficient to raise the temperature of the first layer to at least the liquidus temperature of the metal alloy; allowing at least a portion of the first layer to cool to a temperature sufficient to allow the metal alloy to recrystallize; forming a second layer of the blended mixture on the first layer; and repeating the subjecting and allowing steps on the second layer to form an additional portion of the metal alloy article.

An additive manufacturing method of producing a metal alloy article may involve: Providing a supply of a metal alloy in powder form; providing a supply of a nucleant material, the nucleant material lowering the nucleation energy required to crystallize the metal alloy; blending the supply of metal alloy powder and nucleant material to form a blended mixture; forming the blended mixture into a first layer; subjecting at least a portion of the first layer to energy sufficient to raise the temperature of the first layer to at least the liquidus temperature of the metal alloy; allowing at least a portion of the first layer to cool to a temperature sufficient to allow the metal alloy to recrystallize; forming a second layer of the blended mixture on the first layer; and repeating the subjecting and allowing steps on the second layer to form an additional portion of the metal alloy article.

Provided are a Sn—Ti alloy powder for a superconducting wire, the Sn—Ti alloy powder making it possible to improve superconducting characteristics by minimizing the size of Sn—Ti particles dispersed in a Sn-based alloy, a method for preparing the same, and a method for manufacturing a superconducting wire using the same, wherein a Sn—Ti alloy is melted to produce a Sn—Ti intermetallic compound having an average particle size of 3 μm or less, and a content of Ti in the entire alloy is 0.5 wt % to 3 wt %, and the method of preparing the Sn—Ti alloy powder for a superconducting wire includes: a Sn—Ti alloy melting step of melting a Sn—Ti alloy or a Sn—Ti alloy processed material; and a Sn—Ti alloy powder formation step of spraying and solidifying a molten Sn—Ti alloy through a nozzle in an inert gas atmosphere.

The present invention relates to the composition and production of an engineered degradable metal matrix composite that is useful in constructing temporary systems requiring wear resistance, high hardness, and/or high resistance to deformation in water-bearing applications such as, but not limited to, oil and gas completion operations.

The present invention relates to the composition and production of an engineered degradable metal matrix composite that is useful in constructing temporary systems requiring wear resistance, high hardness, and/or high resistance to deformation in water-bearing applications such as, but not limited to, oil and gas completion operations.

An Al—Sc alloy sputtering target. The target comprising from 1.0 at % to 65 at % scandium and from 35 at % to 99 at % aluminum and having a microstructure including a first aluminum matrix phase and a second phase dispersed uniformly therethrough. The second phase comprises one or more compounds corresponding to the formula Sc.sub.xAl.sub.y, where x is from 1 to 2 and y is from 0 to 3.

An Al—Sc alloy sputtering target. The target comprising from 1.0 at % to 65 at % scandium and from 35 at % to 99 at % aluminum and having a microstructure including a first aluminum matrix phase and a second phase dispersed uniformly therethrough. The second phase comprises one or more compounds corresponding to the formula Sc.sub.xAl.sub.y, where x is from 1 to 2 and y is from 0 to 3.

A degradable, high-strength zinc composition suitable for use in producing degradable tools and components for in use in oil and gas and related application fields.