A method for preparing a tantalum power of capacitor grade, comprising: solid tantalum nitride is added when potassium fluotantalate is reduced by sodium. The method increases the nitrogen content in the tantalum powder, and at the same time improves the electrical performance of the tantalum powder. The specific capacitance is increased, and the leakage current and loss is improved. The qualification rate of the anode and the capacitor product is also improved. The method is characterized in that the nitrogen in the tantalum nitride diffuses between the particles of the tantalum powder, with substantially no loss, and thus the nitrogen content is accurate and controllable.

Provided is a method for producing highly pure titanium metal powder or titanium alloy powder which may be used in various fields. The method includes steps of: a) partially reducing each of at least one metal oxide and a titanium oxide; b) preparing a first mixture by mixing the partially reduced metal oxide and titanium oxide together; c) preparing a second mixture by mixing the first mixture with calcium hydride; and d) producing titanium metal or a titanium alloy by completely reducing the second mixture.

Provided is a method for producing highly pure titanium metal powder or titanium alloy powder which may be used in various fields. The method includes steps of: a) partially reducing each of at least one metal oxide and a titanium oxide; b) preparing a first mixture by mixing the partially reduced metal oxide and titanium oxide together; c) preparing a second mixture by mixing the first mixture with calcium hydride; and d) producing titanium metal or a titanium alloy by completely reducing the second mixture.

A nanofiber based micro-structured material including metal fibers with metal oxide coatings and methods are shown. In one example, nanofiber based micro-structured material is used as an electrode in a battery, such as a lithium ion battery, where the nanofibers of micro-structured material form a nanofiber cloth with free-standing, core-shell structure.

A nanofiber based micro-structured material including metal fibers with metal oxide coatings and methods are shown. In one example, nanofiber based micro-structured material is used as an electrode in a battery, such as a lithium ion battery, where the nanofibers of micro-structured material form a nanofiber cloth with free-standing, core-shell structure.

A sintered magnet and a method for producing the same are provided. The method includes producing an R—Fe—B-based magnet powder by a reduction-diffusion method, adding a R—Al—Cu powder as a sintering agent to the R—Fe—B-based magnet powder to form a mixed powder, wherein the R—Al—Cu powder is an alloy of R, Al and Cu, and R is Nd, Pr, Dy, Tb or Ce, and sintering the mixed powder to form a sintered magnet.

The present invention relates to [1] a process for producing a metal fine particle dispersion containing metal fine particles (a) dispersed with a polymer B, including the step 1 of mixing a metal oxide A, the polymer B and a compound C with each other, in which the polymer B contains a hydrophilic group; the compound C is a dihydric alcohol represented by the general formula (1); and the metal fine particles (a) have a cumulant average particle size of not more than 50 nm, and [2] an ink containing the metal line particle dispersion obtained by the production process described in the above [1].

Process for producing a titanium alloy material, such as a titanium aluminum alloy, are provided. The process includes reduction of TiCl.sub.4, which includes a titanium ion (Ti.sup.4+), through intermediate ionic states of an AlCl.sub.3-based salt solution that includes Ti.sup.3+ and an AlCl.sub.3-based salt solution that includes Ti.sup.2+, which may then undergo a disproportionation reaction to form the titanium aluminum alloy.

Process for producing a titanium alloy material, such as a titanium aluminum alloy, are provided. The process includes reduction of TiCl.sub.4, which includes a titanium ion (Ti.sup.4+), through intermediate ionic states of an AlCl.sub.3-based salt solution that includes Ti.sup.3+ and an AlCl.sub.3-based salt solution that includes Ti.sup.2+, which may then undergo a disproportionation reaction to form the titanium aluminum alloy.

One embodiment of the present invention includes single-crystal particles of a TbCu.sub.7 type samarium-iron-nitrogen based alloy in an anisotropic magnet powder.