Abstract: The present invention relates to a composition of a hot-melt adhesive film and a method for producing a shoe sole. The composition of the hot-melt adhesive film comprises a hot-melt adhesive material and an electromagnetic radiation absorbing material. The hot-melt adhesive material includes ethylene vinyl acetate and thermoplastic materials. The electromagnetic radiation absorbing material is uniformly dispersed in the hot-melt adhesive material. Energy of an electromagnetic radiation can be absorbed by the electromagnetic radiation absorbing material, thereby producing thermal energy, further increasing temperature and adhering property of the hot-melt adhesive film. Therefore, a midsole and an outsole of the shoe sole can be adhered by the hot-melt adhesive film. Further, the hot-melt adhesive film is made from recyclable materials. Therefore, the hot-melt adhesive film is fully recyclable.

Abstract: The present invention relates to a composition of a hot-melt adhesive film and a method for producing a shoe sole. The composition of the hot-melt adhesive film comprises a hot-melt adhesive material and an electromagnetic radiation absorbing material. The hot-melt adhesive material includes ethylene vinyl acetate and thermoplastic materials. The electromagnetic radiation absorbing material is uniformly dispersed in the hot-melt adhesive material. Energy of an electromagnetic radiation can be absorbed by the electromagnetic radiation absorbing material, thereby producing thermal energy, further increasing temperature and adhering property of the hot-melt adhesive film. Therefore, a midsole and an outsole of the shoe sole can be adhered by the hot-melt adhesive film. Further, the hot-melt adhesive film is made from recyclable materials. Therefore, the hot-melt adhesive film is fully recyclable.

Abstract: A method for regeneration of a carbon dioxide absorbent includes steps of a) bringing a used carbon dioxide absorbent in contact with a carbon-containing dielectric material to form a dielectric energy-susceptible combination, and b) subjecting the dielectric energy-susceptible combination to a dielectric heating to remove carbon dioxide from the used carbon dioxide absorbent for the regeneration.

Abstract: A method of capturing carbon dioxide from a source thereof includes contacting a carbon dioxide-containing source with a reactive solution that includes an absorption agent so that carbon dioxide in the carbon dioxide-containing source is absorbed by the absorption agent. The absorption agent may be potassium phosphate, potassium ethylenediamine-tetraacetate (potassium EDTA), a potassium monocarboxylate having a total of 12 or less carbon atoms, or combinations thereof.

Abstract: A nano-nickel catalyst and a hydrogenation device of carbon oxides are provided. The hydrogenation device is configured to reduce the carbon oxides to form low carbon hydrocarbons. The nano-nickel catalyst has a metallic nickel body and a plurality of microstructures connecting with at least one surface of the metallic nickel body. The microstructures are sharp, and have a length-diameter ratio ranging from 2 to 5.

Abstract: A nano-nickel catalyst and a hydrogenation device of carbon oxides are provided. The hydrogenation device is configured to reduce the carbon oxides to form low carbon hydrocarbons. The nano-nickel catalyst has a metallic nickel body and a plurality of microstructures connecting with at least one surface of the metallic nickel body. The microstructures are sharp, and have a length-diameter ratio ranging from 2 to 5.

Abstract: A method of capturing carbon dioxide from a source thereof includes contacting a carbon dioxide-containing source with a reactive solution that includes an absorption agent so that carbon dioxide in the carbon dioxide-containing source is absorbed by the absorption agent. The absorption agent may be potassium phosphate, potassium ethylenediamine-tetraacetate (potassium EDTA), a potassium monocarboxylate having a total of 12 or less carbon atoms, or combinations thereof.