The invention relates to a method for sealing a fuel cell (5) and to a fuel cell (5) which is produced using such a method. The fuel cell (5) has at least one membrane-electrode unit (42) and bipolar plates (18, 22). The method has the steps of attaching a seal material (54) to at least one side of the membrane-electrode unit (42) in a bonded manner, attaching a precursor (62) to seal points (58) of the at least one bipolar plate (18, 22), placing the at least one bipolar plate (18, 22) on the membrane-electrode unit (42) such that the seal points (58) together with the precursor (62) come into contact with the seal material (54), and pressing the at least one bipolar plate (18, 22) and the membrane-electrode unit (42) together under the effect of pressure and/or temperature such that the seal material (54) forms a bonded connection to the at least one bipolar plate (18, 22) and to the membrane electrode unit (42).

Provided is an energy harvesting device for producing electric power by conduction of alkali ions, including a laminated film in which two-dimensional (2D) materials are laminated and assembled, wherein the laminated film includes a first region into which alkali ions are introduced, a second region into which alkali ions are introduced at a concentration lower than that of the first region or into which alkali ions are not introduced, and a third region located between the first region and the second region to divide the first region and the second region, and in which an interlayer distance between the 2D materials is fixed by physical constraints.

Provided is an energy harvesting device for producing electric power by conduction of alkali ions, including a laminated film in which two-dimensional (2D) materials are laminated and assembled, wherein the laminated film includes a first region into which alkali ions are introduced, a second region into which alkali ions are introduced at a concentration lower than that of the first region or into which alkali ions are not introduced, and a third region located between the first region and the second region to divide the first region and the second region, and in which an interlayer distance between the 2D materials is fixed by physical constraints.

A frame gasket may include a flat base, which is positioned along the edge of stack constitutional parts and which includes a first elastic base and reinforced fibers mixed therein to ensure sealing of a fuel cell stack, and first projection units, which project over the base and which include a second elastic base.

A frame gasket may include a flat base, which is positioned along the edge of stack constitutional parts and which includes a first elastic base and reinforced fibers mixed therein to ensure sealing of a fuel cell stack, and first projection units, which project over the base and which include a second elastic base.

Disclosed herein are a method of manufacturing a fuel cell, and a fuel cell manufactured according to the method. The method includes bonding a sub-gasket, provided with an air inlet and a hydrogen inlet, to a side surface of a three-layer membrane-electrode assembly (MEA) including an electrolyte membrane, a cathode located on one surface of the electrolyte membrane, and an anode located on the other surface of the electrolyte membrane; stacking a gas diffusion layer, which comprises an antioxidant precursor, on at least one of the cathode and the anode and preparing a five-layer MEA; and applying a current to the five-layer MEA and moving an antioxidant, which is derived from the antioxidant precursor, to the electrolyte membrane.

An object of the present disclosure is to provide a method for manufacturing a fuel cell that ensures developing a high adhesive strength to a separator. One aspect of an embodiment is a method for manufacturing a fuel cell where a pair of separators are mutually bonded with a sealing member. The sealing member includes a thermoplastic resin containing a crystalline polymer as an adhesive layer. The method for manufacturing the fuel cell includes: preparing a stack structure in which the sealing member is disposed between the pair of separators; heating the stack structure at a melting point or higher of the thermoplastic resin; after the heating, holding the stack structure in a temperature range of ±10° C. of a crystallization temperature of the thermoplastic resin to promote a crystallization of the thermoplastic resin; and after the holding, further cooling the stack structure.

An object of the present disclosure is to provide a method for manufacturing a fuel cell that ensures developing a high adhesive strength to a separator. One aspect of an embodiment is a method for manufacturing a fuel cell where a pair of separators are mutually bonded with a sealing member. The sealing member includes a thermoplastic resin containing a crystalline polymer as an adhesive layer. The method for manufacturing the fuel cell includes: preparing a stack structure in which the sealing member is disposed between the pair of separators; heating the stack structure at a melting point or higher of the thermoplastic resin; after the heating, holding the stack structure in a temperature range of ±10° C. of a crystallization temperature of the thermoplastic resin to promote a crystallization of the thermoplastic resin; and after the holding, further cooling the stack structure.

A method for manufacturing a separator for a fuel cell includes: a roughening step of forming a roughened region in a surface of a separator body; and a molding step of molding a gasket on the surface of the separator body. In the molding step, the gasket is molded in an area including at least a part of the roughened region.

A method for manufacturing a separator for a fuel cell includes: a roughening step of forming a roughened region in a surface of a separator body; and a molding step of molding a gasket on the surface of the separator body. In the molding step, the gasket is molded in an area including at least a part of the roughened region.