The present invention relates to mesoporous silica embedded with alloy particles, and a preparation method thereof, and it is possible to prevent the release of metal particles to the outside because the inside of spherical mesoporous silica is embedded with metal nanoparticles, and as the aggregation of the metal is prevented, the stability is excellent and the production yield is high during the preparation process, so that mesoporous silica can be mass-produced, the efficacy of metal nanoparticles may be maintained by preventing the oxidation of metal nanoparticles, and mesoporous silica can be produced at low costs. Further, the inside of pores of mesoporous silica is embedded with metal nanoparticles, so that the discoloration and smell change phenomenon does not occur, and the far-infrared emission and deodorization effects are excellent.

The present invention relates to mesoporous silica embedded with alloy particles, and a preparation method thereof, and it is possible to prevent the release of metal particles to the outside because the inside of spherical mesoporous silica is embedded with metal nanoparticles, and as the aggregation of the metal is prevented, the stability is excellent and the production yield is high during the preparation process, so that mesoporous silica can be mass-produced, the efficacy of metal nanoparticles may be maintained by preventing the oxidation of metal nanoparticles, and mesoporous silica can be produced at low costs. Further, the inside of pores of mesoporous silica is embedded with metal nanoparticles, so that the discoloration and smell change phenomenon does not occur, and the far-infrared emission and deodorization effects are excellent.

A conductive ink is provided, which includes an ink solvent and a conductive composition dispersed in the ink solvent. The conductive composition includes a silver nanoparticle and a molecular chain of polyaniline formed on a surface of the silver nanoparticle. A method for preparing a conductive ink and a flexible display device are further provided. The conductive ink has good film forming property and good conductivity.

A conductive ink is provided, which includes an ink solvent and a conductive composition dispersed in the ink solvent. The conductive composition includes a silver nanoparticle and a molecular chain of polyaniline formed on a surface of the silver nanoparticle. A method for preparing a conductive ink and a flexible display device are further provided. The conductive ink has good film forming property and good conductivity.

A low-temperature high-performance thermoelectric material possesses a chemical formula of (Ag.sub.yCu.sub.2−y).sub.1−xTe.sub.1−zSe.sub.z, wherein −0.025≤x≤0.075, 0.6≤y≤1.4, 0<z≤0.25, diffraction peaks of a main phase of the thermoelectric material are indexed as a cubic structure at room temperature of 300 K, a highest ZT value between 300 K and 673 K is in range of 0.4 to 1.6, an average ZT value (ZT).sub.avg is in range of 0.2 to 1.4. The highest ZT value of this material at the room temperature is comparable to that of Bi.sub.2Te.sub.3, which is an excellent complement to existing low-temperature thermoelectric materials. At the same time, the present invention also indicates a new strategy to improve the low-temperature thermoelectric performance of Cu.sub.2X-based (here, X is S, Se, Te) materials, and lays a foundation for the application of Cu.sub.2X-based materials in the field of low-temperature thermoelectricity.

The present invention refers to the recovery of high-value metals such as gold and silver from ores containing them by the leaching process that is carried out in tanks or reactors, and to the destruction of cyanide, which is carried out in cyanide destruction (detox) tanks at the end of the leaching process, to avoid damage to the environment. An oxygen diffuser with a specific design is provided which is used in pulp leaching tanks and in cyanide destruction (detox) tanks containing residual pulp, with the application of oxygen, whereby better results are obtained in the recovery of metals, in the application of oxygen and in retention time, among others.

A sintering powder comprising: a particulate having a mean longest diameter of less than 10 microns, wherein at least some of the particles forming the particulate comprise a metal at least partially coated with a capping agent. A sintering paste and sintering film comprising the sintering powder. A method for making a sintered joint by sintering the sintering powder, paste, or film in the vicinity of two or more workpieces.

A sintering powder comprising: a particulate having a mean longest diameter of less than 10 microns, wherein at least some of the particles forming the particulate comprise a metal at least partially coated with a capping agent. A sintering paste and sintering film comprising the sintering powder. A method for making a sintered joint by sintering the sintering powder, paste, or film in the vicinity of two or more workpieces.

The recovery of noble metal(s) from noble-metal-containing material is generally described. The noble metal(s) can be recovered selectively, in some cases, such that noble metal(s) is at least partially separated from non-noble-metal material within the material. Noble metal(s) may be recovered from noble-metal-containing material using mixtures of acids, in some instances. In some cases, the mixture can comprise nitric acid and/or another source of nitrate ions and at least one supplemental acid, such as sulfuric acid, phosphoric acid, and/or a sulfonic acid. The amount of nitrate ions within the mixture can be, in some instances, relatively small compared to the amount of supplemental acid within the mixture. In some cases, the recovery of noble metal(s) using the acid mixtures described herein can be enhanced by transporting an electric current between an electrode and the noble metal(s) of the noble-metal-containing material. In some cases, acid mixtures can be used to recover silver from particular types of scrap materials, such as scrap material comprising silver metal and cadmium oxide and/or scrap material comprising silver metal and tungsten metal.

The recovery of noble metal(s) from noble-metal-containing material is generally described. The noble metal(s) can be recovered selectively, in some cases, such that noble metal(s) is at least partially separated from non-noble-metal material within the material. Noble metal(s) may be recovered from noble-metal-containing material using mixtures of acids, in some instances. In some cases, the mixture can comprise nitric acid and/or another source of nitrate ions and at least one supplemental acid, such as sulfuric acid, phosphoric acid, and/or a sulfonic acid. The amount of nitrate ions within the mixture can be, in some instances, relatively small compared to the amount of supplemental acid within the mixture. In some cases, the recovery of noble metal(s) using the acid mixtures described herein can be enhanced by transporting an electric current between an electrode and the noble metal(s) of the noble-metal-containing material. In some cases, acid mixtures can be used to recover silver from particular types of scrap materials, such as scrap material comprising silver metal and cadmium oxide and/or scrap material comprising silver metal and tungsten metal.