Abstract: A catalytic solution for a halide ion battery, which is an aqueous solution containing a quaternary ammonium halide salt or a hydrate thereof at 9.0 mol/kg to 11.0 mol/kg, is an electrolyte for a halide ion battery that has excellent safety and a wide potential window.

Abstract: Disclosed is a fuel cell reaction layer which is excellent in durability and heat resistance while having a low operation temperature. In addition, supply of an oxygen gas to the fuel cell reaction layer is hardly disturbed. Also disclosed are a fuel cell and a method for producing such a fuel cell reaction layer. Specifically disclosed is a fuel cell reaction layer wherein a mixed conductive catalyst is used. The mixed conductive catalyst includes a conductive carrier composed of an electron conductor formed of carbon and a proton conductor formed of an inorganic material. The electron conductor is an inorganic material comprising a polymerized and carbonized organic monomer: the proton conductor is an inorganic material, and the electron conductor and the proton conductor are bonded together. In addition, a water-repellent carbon is further blended in this fuel cell reaction layer.

Abstract: A fuel cell includes a reaction layer composed of a catalyst carrier, formed of a compound having inorganic electron conductor units and inorganic proton conductor units in its molecular structure, and a catalyst supported on the catalyst carrier.

Abstract: Disclosed is a fuel cell reaction layer which is excellent in durability and heat resistance while having a low operation temperature. In addition, supply of an oxygen gas to the fuel cell reaction layer is hardly disturbed. Also disclosed are a fuel cell and a method for producing such a fuel cell reaction layer. Specifically disclosed is a fuel cell reaction layer wherein a mixed conductive catalyst, which is obtained by loading a Pt catalyst onto a mixed conductive carrier wherein an electron conductor composed of carbon and a proton conductor composed of a phosphoric acid condensate are hybridized, is used. In addition, a water-repellent carbon is further blended in this fuel cell reaction layer. The mixed conductive carrier is obtained by carbonizing a polymer precursor which is obtained by mixing and copolymerizing a resorcinol and trimethyl phosphate.

Abstract: A mixed conductor of this invention includes an electron conductor made of a carbon-based inorganic material imparted electron conduction by causing a main chain to have a ? bond, and a proton conductor made of an inorganic material having proton conduction, and the electron conductor and the proton conductor are fixed to each other by one of or all of a covalent bond, intercalation, and inclusion.

Abstract: A fuel cell includes a reaction layer composed of a catalyst carrier, formed of a compound having inorganic electron conductor units and inorganic proton conductor units in its molecular structure, and a catalyst supported on the catalyst carrier.

Abstract: The mixed conductor of the invention includes an electron conductor made of a carbon-based inorganic material with a main chain having a ? bond for conduction of electrons, and a proton conductor made of an inorganic material, wherein the electron conductor and the proton conductor are attached to each other by at least one of covalent bonding, intercalation, and inclusion.

Abstract: A mixed conductor of this invention includes an electron conductor made of a carbon-based inorganic material imparted electron conduction by causing a main chain to have a ? bond, and a proton conductor made of an inorganic material having proton conduction, and the electron conductor and the proton conductor are fixed to each other by one of or all of a covalent bond, intercalation, and inclusion.

Abstract: In a first process step, intermediate product dehydration polymerization of a hydrocarbon-based polymer including a metal alkoxide and phosphoric acid is performed to obtain an intermediate product. Then, in a second process step, the intermediate product is irradiated by microwaves with a wavelength that selectively imparts energy to a hydroxyl group included in the intermediate product. As a result, an electrolyte membrane is obtained that is composed from a skeleton formed from a hydrocarbon-based polymer and phosphoric acid that is proton conductive.

Abstract: In a first process step, intermediate product dehydration polymerization of a hydrocarbon-based polymer including a metal alkoxide and phosphoric acid is performed to obtain an intermediate product. Then, in a second process step, the intermediate product is irradiated by microwaves with a wavelength that selectively imparts energy to a hydroxyl group included in the intermediate product. As a result, an electrolyte membrane is obtained that is composed from a skeleton formed from a hydrocarbon-based polymer and phosphoric acid that is proton conductive.

Abstract: A mixed conductor of this invention includes an electron conductor made of a carbon-based inorganic material imparted electron conduction by causing a main chain to have a &pgr; bond, and a proton conductor made of an inorganic material having proton conduction, and the electron conductor and the proton conductor are fixed to each other by one of or all of a covalent bond, intercalation, and inclusion.

Abstract: There are provided a gaseous-diffusion electrode which can exhibit sufficient gas-supplying ability and gas-discharging ability and an excellent durability even when partly immersed in an electrolysis solution; and an electrochemical reactor using the gaseous-diffusion electrode. A porous membrane 15 which is permeable to gas but not to an electrolysis solution is fixed to the surface of the gaseous-diffusion layer 13 of a gaseous-diffusion electrode 11 obtained by joining a reaction layer 12 supporting a catalyst metal and a gaseous-diffusion layer 13 to each other, so as to cover the surface of the gaseous-diffusion layer 13. When a gas passageway member 17 serving as gas passageway to the gaseous-diffusion layer 13 is inserted between the surface of the gaseous-diffusion layer 13 and the porous membrane 15, the gas-supplying ability and the gas-discharging ability becomes greatly improved.