Compositions comprising high levels of high specific activity copper-64, and process for preparing said compositions. The compositions comprise from about 2 Ci to about 15 Ci of copper-64 and have specific activities up to about 3800 mCi copper-64 per microgram of copper. The processes for preparing said compositions comprise bombarding a nickel-64 target with a low energy, high current proton beam, and purifying the copper-64 from other metals by a process comprising ion exchange chromatography or a process comprising a combination of extraction chromatography and ion exchange chromatography.

Compositions comprising high levels of high specific activity copper-64, and process for preparing said compositions. The compositions comprise from about 2 Ci to about 15 Ci of copper-64 and have specific activities up to about 3800 mCi copper-64 per microgram of copper. The processes for preparing said compositions comprise bombarding a nickel-64 target with a low energy, high current proton beam, and purifying the copper-64 from other metals by a process comprising ion exchange chromatography or a process comprising a combination of extraction chromatography and ion exchange chromatography.

An innovative high-energy oxidative method using metallic copper and chlorine liquid to produce a superior copper chloride II element using electromagnetic induction and magnetic forces. This invention involves copper undergoing oxidation while in its highest energy state according to basic principles of electromotive forces described in Faraday's law. The copper attaches to a magnetic receptacle and held in place by a copper lid cover. Research studies demonstrate that metallic copper is not magnetic; however, when a magnetic field approaches copper, the electrons and subatomic particles forms a higher resistance against the magnets—Generating a force field response towards the approaching magnets. The oxidation of copper in its highest energy state provides additional improvements and benefits in copper's antimicrobial and antiviral properties. This new method for oxidizing copper chloride in its highest subatomic energy state provides vast improvements and coverage in the fight against microorganisms and the invisible pathogens abroad.

An innovative high-energy oxidative method using metallic copper and chlorine liquid to produce a superior copper chloride II element using electromagnetic induction and magnetic forces. This invention involves copper undergoing oxidation while in its highest energy state according to basic principles of electromotive forces described in Faraday's law. The copper attaches to a magnetic receptacle and held in place by a copper lid cover. Research studies demonstrate that metallic copper is not magnetic; however, when a magnetic field approaches copper, the electrons and subatomic particles forms a higher resistance against the magnets—Generating a force field response towards the approaching magnets. The oxidation of copper in its highest energy state provides additional improvements and benefits in copper's antimicrobial and antiviral properties. This new method for oxidizing copper chloride in its highest subatomic energy state provides vast improvements and coverage in the fight against microorganisms and the invisible pathogens abroad.

Compositions comprising high levels of high specific activity copper-64, and process for preparing said compositions. The compositions comprise from about 2 Ci to about 15 Ci of copper-64 and have specific activities up to about 3800 mCi copper-64 per microgram of copper. The processes for preparing said compositions comprise bombarding a nickel-64 target with a low energy, high current proton beam, and purifying the copper-64 from other metals by a process comprising ion exchange chromatography or a process comprising a combination of extraction chromatography and ion exchange chromatography.

Compositions comprising high levels of high specific activity copper-64, and process for preparing said compositions. The compositions comprise from about 2 Ci to about 15 Ci of copper-64 and have specific activities up to about 3800 mCi copper-64 per microgram of copper. The processes for preparing said compositions comprise bombarding a nickel-64 target with a low energy, high current proton beam, and purifying the copper-64 from other metals by a process comprising ion exchange chromatography or a process comprising a combination of extraction chromatography and ion exchange chromatography.

Disclosed are basic copper chloride particulate matter and a preparation method therefor. The basic copper chloride particulate matter is mainly composed of basic copper chloride particles, and the basic copper chloride particles, with a particle size of 60-250 m, in the basic copper chloride particulate matter comprise 97% or more of the total mass of the basic copper chloride particulate matter.

Disclosed are basic copper chloride particulate matter and a preparation method therefor. The basic copper chloride particulate matter is mainly composed of basic copper chloride particles, and the basic copper chloride particles, with a particle size of 60-250 m, in the basic copper chloride particulate matter comprise 97% or more of the total mass of the basic copper chloride particulate matter.

The present invention relates to a functional copper sulfide composition and a functional fiber prepared therefrom, and more particularly, a functional copper sulfide composition comprising a copper salt, a metal salt, a reducing agent, a sulfur compound, a catalyst, a poly amine, an alkali compound and a pH adjusting agent; and a functional fiber prepared by treating the composition with a fiber.

The present invention relates to a functional copper sulfide composition and a functional fiber prepared therefrom, and more particularly, a functional copper sulfide composition comprising a copper salt, a metal salt, a reducing agent, a sulfur compound, a catalyst, a poly amine, an alkali compound and a pH adjusting agent; and a functional fiber prepared by treating the composition with a fiber.