초록 ▼

The invention relates to metal-treated particles, methods for their preparation and methods for using metal-treated particles for, e.g., remediation of process waste-water, sewage, contaminated groundwater aquifers, and soil containing harmful contaminants. Another aspect of the invention relates to

The invention relates to metal-treated particles, methods for their preparation and methods for using metal-treated particles for, e.g., remediation of process waste-water, sewage, contaminated groundwater aquifers, and soil containing harmful contaminants. Another aspect of the invention relates to a metal-treated particle comprising a ferrosoferric oxide core and a metal supported on the core, where the average diameter or other largest transverse dimension of the core is from about 75 nm to about 990 nm and the amount of metal supported on the core is from about 8% to about 22% by weight, based on the weight of the metal-treated particle.

대표청구항 ▼

What is claimed is: 1. A heterogeneous metal-treated particle comprising a core comprising ferrosoferric oxide, ferric trioxide, cobalt oxide, perlite, or any mixture thereof and a metal supported on the core, wherein the core and the metal supported on the core comprise different materials, and th

What is claimed is: 1. A heterogeneous metal-treated particle comprising a core comprising ferrosoferric oxide, ferric trioxide, cobalt oxide, perlite, or any mixture thereof and a metal supported on the core, wherein the core and the metal supported on the core comprise different materials, and the metal-treated particle promotes a remediation reaction reactive surface for the metal supported on the core, wherein during the remediation reaction there is no chemical reaction with the core. 2. The metal-treated particle of claim 1, wherein the average diameter or other largest transverse dimension of the core is from about 5 nm to about 1100 nm. 3. The metal-treated particle of claim 1, wherein the average diameter or other largest transverse dimension of the core is from about 5 nm to about 990 nm. 4. The metal-treated particle of claim 1, wherein the core is ferrosoferric oxide. 5. The metal-treated particle of claim 1, wherein the metal supported on the core comprises a transition metal. 6. The metal-treated particle of claim 5, wherein the transition metal supported on the core is iron, copper, nickel, cobalt, silver, gold, palladium, platinum, or any mixture thereof. 7. The metal-treated particle of claim 6, wherein the transition metal supported on the core is nickel and palladium. 8. The metal-treated particle of claim 6, wherein the transition metal supported on the core comprises iron. 9. The metal-treated particle of claim 8, wherein the transition metal supported on the core comprises iron and nickel. 10. The metal-treated particle of claim 8, wherein the transition metal supported on the core comprises iron and palladium. 11. The metal-treated particle of claim 8, wherein the transition metal supported on the core comprises iron, nickel and palladium. 12. The metal-treated particle of claim 5, wherein the amount of metal supported on the core is from about 1% to about 90% by weight, based on the weight of the metal-treated particle. 13. The metal-treated particle of claim 12, wherein the amount of metal supported on the core is from about 5% to about 25% by weight, based on the weight of the metal-treated particle. 14. The metal-treated particle of claim 13, wherein the amount of metal supported on the core is from about 8% to about 22% by weight, based on the weight of the metal-treated particle. 15. The metal-treated particle of claim 1, wherein the average diameter or other largest transverse dimension of the particle is from less than about 10 nm to about 1100 nm. 16. The metal-treated particle of claim 1, wherein the average diameter or other largest transverse dimension of the particle is from less than about 10 nm to about 990 nm. 17. A heterogeneous metal-treated particle comprising a ferrosoferric oxide core and a metal supported on the core, wherein the average diameter or other largest transverse dimension of the core is from about 75 nm to about 990 nm; and the amount of metal supported on the core is from about 8% to about 22% by weight, based on the weight of the metal-treated particle, wherein the core and the metal supported on the core comprise different materials, and wherein the heterogeneous metal-treated particle remediation reaction reacts substantially similarly to a homogenous particle comprised of the metal supported on the code. 18. The metal-treated particle of claim 17, wherein the metal supported on the core is iron, copper, nickel, cobalt, palladium, platinum, or any mixture thereof. 19. A heterogeneous metal-treated particle comprising a core particle and a metal supported on the core formed by a method comprising: (a) providing a core particle, a metal-supplying agent and a reductant, (b) contacting the metal-supply agent and the reductant in the presence of the core particle to form a metal supported on the core particle, and (c) optionally, recovering the metal-treated particle, wherein the core particle comprises ferrosoferric oxide, ferric trioxide, nickel oxide, cobalt oxide, magnesium oxide, perlite, or any mixture thereof, and wherein the core and the metal supported on the core comprise different materials, and wherein the metal-treated particle provides a remediation reaction reactive surface substantially similar to a homogenous particle comprised of the metal supported on the core. 20. The metal-treated particle of claim 19, wherein the metal-supplying agent comprises a transition metal halide, a transition metal sulfate, a transition metal acetate, a hydrate thereof, or any mixture thereof. 21. The metal-treated particle of claim 20, wherein the reductant comprises an alkali metal hydride, an alkali metal azide, or any mixture thereof. 22. The metal-treated particle of claim 21, wherein the reductant is sodium borohydride, potassium borohydride, lithium borohydride, sodium azide, potassium azide, or any mixture thereof. 23. The metal-treated particle of claim 19, wherein the metal-supplying agent is ferric chloride and the reductant is sodium borohydride. 24. The metal-treated particle of claim 19, wherein the contacting is conducted in a fluid medium, optionally, a liquid medium. 25. The metal-treated particle of claim 19, wherein the contacting is conducted at a temperature of from about 15° C. to about 30° C. 26. The metal-treated particle of claim 19, wherein the reductant comprises an alkali metal hydride, an alkali metal azide, a lithium alkyl, a magnesium alkyl, an aluminum alkyl, or any mixture thereof.