Abstract: A method of using a metal powder in an additive manufacturing process. The method includes providing the metal powder, and using the metal powder in the additive manufacturing process. The metal powder is a metal which is selected from tantalum and impurities, titanium and impurities, niobium and impurities, an alloy of tantalum, niobium and impurities, an alloy of titanium, niobium and impurities, and an alloy of tantalum, titanium, niobium and impurities. Particles of the metal powder have a dendritic microstructure. Particles of the metal powder have an average aspect ratio ?A of from 0.7 to 1, where ?A=XFeret min/XFeret max.

Abstract: A three-dimensional article is obtained by a process which includes providing a metal powder, and using the metal powder to build up the three-dimensional article layer by layer. The metal powder is a metal which is selected from the group of tantalum and impurities, titanium and impurities, niobium and impurities, an alloy of tantalum, niobium and impurities, an alloy of titanium, niobium and impurities, and an alloy of tantalum, titanium, niobium and impurities. Particles of the metal powder have a dendritic microstructure. Particles of the metal powder have an average aspect ratio TA of from 0.7 to 1, where ?A=xFeret min/xFeret max.

Abstract: The present invention relates to metal powders which are suitable to be employed in 3D printing processes as well as a process for the production of said powders.

Abstract: The present invention relates to metal powders which are suitable to be employed in 3D printing processes as well as a process for the production of said powders.

Abstract: The invention comprises semifinished products with a structured surface, the semifinished product comprising an oxidized and subsequently re-reduced surface containing at least one refractory metal, and also a process for their production and their use for producing high-capacitance components.

Abstract: The invention comprises semifinished products with a structured surface, the semifinished product comprising an oxidized and subsequently re-reduced surface containing at least one refractory metal, and also a process for their production and their use for producing high-capacitance components.

Abstract: A method for producing an electrode for a capacitor, particularly an electrolyte capacitor, proceeding from an alloy with a component A and a component B, wherein the surface energy of the component A is greater than the surface energy of the component B and wherein a layer containing the component B arises at the surface of a body containing the component A by oxidation-induced segregation and tempering of the alloy. A method for producing a capacitor with such an electrode is also disclosed. The long-time stability of the electrode or, respectively, of the capacitor can be improved by the production of an intermediate layer which impedes the diffusion of oxygen and which dissolves less oxygen than the electrode body.

Abstract: An electrode for a capacitor having an electrode charge eliminator and an electrode body which is contacted with the electrode charge eliminator and on whose surface a dielectric layer is formed. An intermediate layer blocking the exchange of matter between the dielectric layer and the electrode body is formed between the electrode body and the dielectric layer. The diffusion of oxygen from the dielectric layer into the electrode body is prevented with the aid of the intermediate layer, in particular, so that the electrode exhibits a higher long-time stability.