A catalyst includes a layered double hydroxide and a metal particle. The layered double hydroxide includes ions of at least two transition metals. The metal particle includes at least one transition metal. The metal particle has a surface coated with the layered double hydroxide.

An electrode catalyst for a water electrolysis cell includes a catalyst and a polymer of intrinsic microporosity, and the polymer of intrinsic microporosity is neutral.

Provided are a method for producing an organic substance and a device for producing an organic substance that are capable of efficiently cooling a synthesis gas and of converting the synthesis gas to an organic substance at a high conversion efficiency using a microbial catalyst. A thermally decomposed gas purification/cooling device including a gasification furnace 10 that gasifies waste to generate a thermally decomposed gas, a cyclone 11 through which the thermally decomposed gas discharged from the gasification furnace 10 is passed to recover a dust component in the thermally decomposed gas, and a heat exchanger 20 through which the thermally decomposed gas that has passed through the cyclone 11 is passed to be cooled.

Provided are a method for producing an organic substance and a device for producing an organic substance that are capable of efficiently cooling a synthesis gas and of converting the synthesis gas to an organic substance at a high conversion efficiency using a microbial catalyst. A thermally decomposed gas purification/cooling device including a gasification furnace 10 that gasifies waste to generate a thermally decomposed gas, a cyclone 11 through which the thermally decomposed gas discharged from the gasification furnace 10 is passed to recover a dust component in the thermally decomposed gas, and a heat exchanger 20 through which the thermally decomposed gas that has passed through the cyclone 11 is passed to be cooled.

A method for producing hydrogen gas, is disclosed which is characterized by reacting “mineral ion water containing at least alkaline earth metal ions and having pH of 11 or more to 14 or less” and “mineral-supported high-temperature burned carbonaceous substances made by impregnating mineral ion water in an organism-derived carbon precursor and burning the precursor at high temperature”; a mineral-supported high-temperature burned carbonaceous substance for the above-mentioned method of producing of hydrogen gas; and a method for producing mineral ion water for the above-mentioned method of producing hydrogen gas, wherein the mineral ion water is made by dissolving at least oxide, hydroxide, carbonate, or hydrogencarbonate of magnesium or calcium in water to contain alkaline earth metal ions in the water, adjusting pH of the water, and dissolving a water-soluble component of organism-ash in the water.

The present invention provides a method of preparing acetylene (C.sub.2H.sub.2), the method at least comprising the steps of: a) providing a methane-containing stream; b) subjecting the methane-containing stream provided in step a) to non-catalytic pyrolysis, thereby obtaining carbon and hydrogen; c) reacting the carbon obtained in step b) with CaO, thereby obtaining CaC.sub.2 and CO; d) reacting the CaC.sub.2 obtained in step c) with H.sub.2O, thereby obtaining acetylene (C.sub.2H.sub.2) and Ca(OH).sub.2; e) decomposing the Ca(OH).sub.2 obtained in step d), thereby obtaining CaO and H.sub.2O; f) using the CaO as obtained in step e) in the reaction of step c).

The present invention provides a method of preparing acetylene (C.sub.2H.sub.2), the method at least comprising the steps of: a) providing a methane-containing stream; b) subjecting the methane-containing stream provided in step a) to non-catalytic pyrolysis, thereby obtaining carbon and hydrogen; c) reacting the carbon obtained in step b) with CaO, thereby obtaining CaC.sub.2 and CO; d) reacting the CaC.sub.2 obtained in step c) with H.sub.2O, thereby obtaining acetylene (C.sub.2H.sub.2) and Ca(OH).sub.2; e) decomposing the Ca(OH).sub.2 obtained in step d), thereby obtaining CaO and H.sub.2O; f) using the CaO as obtained in step e) in the reaction of step c).

A process for producing syngas including at least H.sub.2 and CO. The process includes the steps of a) generating a transition metal carbide by reacting a corresponding transition metal oxide with a fuel to produce a stream of syngas; and b) combining the transition metal carbide with oxygen to oxidize the transition metal carbide to regenerate the corresponding transition metal oxide, thereby producing a gas output comprising at least one or more oxidized carbon compounds and heat for autothermal operation.

Metallopolymers composed of polymers and catalytically active diiron-disulfide ([2Fe-2S]) complexes are described herein. [FeFe]-hydrogenase mimics have been synthesized and used to initiate polymerization of various monomers to generate metallopolymers containing active [2Fe-2S] sites which serve as catalysts for a hydrogen evolution reaction (HER). Vinylic monomers with polar groups provided water solubility relevant for large scale hydrogen production, leveraging the supramolecular architecture to improve catalysis. Metallopolymeric electrocatalysts displayed high turnover frequency and low overpotential in aqueous media as well as aerobic stability. Metallopolymeric photocatalysts incorporated P3HT ligands to serve as a photosensitizer to promote photoinduced electron transfer to the active complex.

An electrode catalyst for a water electrolysis cell includes a catalyst, a support, and an organic compound. The catalyst is a layered double hydroxide that contains a chelating agent. The support contains a transition metal. The organic compound has an anionic functional group.