A method for producing fine copper particles includes producing fine copper particles having a coating film containing cuprous oxide on a surface by heating copper or a copper compound in a reducing flame formed by a burner. The fine copper particles are produced by adjusting a mixing ratio between a combustible gas and a combustion supporting gas which form the reducing flame such that a volume ratio of CO/CO.sub.2 is in a range of 1.5 to 2.4.

A method for producing fine copper particles includes producing fine copper particles having a coating film containing cuprous oxide on a surface by heating copper or a copper compound in a reducing flame formed by a burner. The fine copper particles are produced by adjusting a mixing ratio between a combustible gas and a combustion supporting gas which form the reducing flame such that a volume ratio of CO/CO.sub.2 is in a range of 1.5 to 2.4.

The present disclosure relates to a stable copper-based core-shell nanoparticle and its process of manufacture. Further, the present disclosure relates to the use of the copper-based core-shell nanoparticles as plasmonic photocatalysts in photocalysis and hydrogen production.

The present disclosure relates to a stable copper-based core-shell nanoparticle and its process of manufacture. Further, the present disclosure relates to the use of the copper-based core-shell nanoparticles as plasmonic photocatalysts in photocalysis and hydrogen production.

The present invention discloses a preparation process of multi-component spherical alloy powder, which adopts a plasma rotation electrode process (PREP) method to prepare the multi-component spherical alloy powder. The multi-component alloy includes at least one of refractory metals and compounds thereof, specifically including tungsten, molybdenum, tantalum, niobium, rhenium, tungsten carbide, tantalum carbide and the like.

The present invention adopts the PREP method to prepare the multi-component spherical alloy powder containing the refractory metals or compound thereof, and the prepared multi-component spherical alloy powder has high sphericity, good fluidity and high tap density, and is low in content of impurity elements and output of hollow powder and satellite powder; compared with other preparation methods, the prepared alloy powder has better performance and is an ideal material for metal 3D printing; and the present invention further solves the problem of difficulty in preparing a round rod with the refractory metals or compound thereof as a base material used in the PREP method, and provides a spatial structure meshing method, a direct element mixing method or a porous framework method to prepare a multi-component alloy rod.

The present invention discloses a preparation process of multi-component spherical alloy powder, which adopts a plasma rotation electrode process (PREP) method to prepare the multi-component spherical alloy powder. The multi-component alloy includes at least one of refractory metals and compounds thereof, specifically including tungsten, molybdenum, tantalum, niobium, rhenium, tungsten carbide, tantalum carbide and the like.

The present invention adopts the PREP method to prepare the multi-component spherical alloy powder containing the refractory metals or compound thereof, and the prepared multi-component spherical alloy powder has high sphericity, good fluidity and high tap density, and is low in content of impurity elements and output of hollow powder and satellite powder; compared with other preparation methods, the prepared alloy powder has better performance and is an ideal material for metal 3D printing; and the present invention further solves the problem of difficulty in preparing a round rod with the refractory metals or compound thereof as a base material used in the PREP method, and provides a spatial structure meshing method, a direct element mixing method or a porous framework method to prepare a multi-component alloy rod.

The dust core comprises a plurality of soft magnetic iron-based particles, a coating layer disposed on each of the surfaces of the soft magnetic iron-based particles, an interstitial layer disposed between the coating layers, and a nanopowder disposed between the soft magnetic iron-based particles. The coating layer is a layer of a compound comprising Fe, Si, O, B and N; and the nanopowder is a powder of a compound comprising O, N and at least one element selected from the group consisting of Fe, Si, Zr, Co, Al, Mg, Mn and Ni.

The dust core comprises a plurality of soft magnetic iron-based particles, a coating layer disposed on each of the surfaces of the soft magnetic iron-based particles, an interstitial layer disposed between the coating layers, and a nanopowder disposed between the soft magnetic iron-based particles. The coating layer is a layer of a compound comprising Fe, Si, O, B and N; and the nanopowder is a powder of a compound comprising O, N and at least one element selected from the group consisting of Fe, Si, Zr, Co, Al, Mg, Mn and Ni.

The instant disclosure is directed to passivated silver nanoparticle coatings and methods of making the same. A method may comprise obtaining a substrate having a surface, exposing the surface to a plurality of silver nanoparticles, applying a nucleating agent to the silver nanoparticles to form a plurality of silver cores, and passivating the silver cores by applying a sulfidation agent to the silver cores to form silver sulfide shells around the silver cores, thereby forming a coating comprising a plurality of sulfidated silver nanoparticles having a core-shell structure. The method may be used to form a coating comprising a plurality of sulfidated silver nanoparticles having a core-shell structure.

The instant disclosure is directed to passivated silver nanoparticle coatings and methods of making the same. A method may comprise obtaining a substrate having a surface, exposing the surface to a plurality of silver nanoparticles, applying a nucleating agent to the silver nanoparticles to form a plurality of silver cores, and passivating the silver cores by applying a sulfidation agent to the silver cores to form silver sulfide shells around the silver cores, thereby forming a coating comprising a plurality of sulfidated silver nanoparticles having a core-shell structure. The method may be used to form a coating comprising a plurality of sulfidated silver nanoparticles having a core-shell structure.