A composite electrode includes two or more types of fibers forming a fiber network, comprising at least a first type of fibers and a second type of fibers. The first type of fibers comprises a first polymer and a first type of particles. The second type of fibers comprises a second polymer and a second type of particles. The second polymer is same as or different from the first polymer. The second type of particles are same as or different from the first type of particles.

In an example, a process includes applying a platinum catalyst ink solution to a polymeric substrate to form a platinum-coated polymeric material having a first catalytic surface area. The process further includes utilizing a laser to process a portion of the platinum-coated polymeric material to form a patterned platinum-coated proton exchange membrane (PEM) material. The patterned platinum-coated PEM material has a second catalytic surface area that is greater than the first catalytic surface area.

A method for preparing a platinum-indium cluster catalyst for a fuel cell, the method including steps of: obtaining a carbon powder, dispersing the carbon powder in a strong oxidizing solution, and performing high-temperature hydrothermal treatment to obtain an activated carbon powder; obtaining a mixed alcohol solution comprising a platinum precursor and an indium precursor; dispersing the activated carbon powder in the mixed alcohol solution, and heat treating the mixed alcohol solution to volatilize an alcohol solvent to obtain a mixed powder; and performing high-temperature treatment on the mixed powder under a mixed gas atmosphere of hydrogen and argon, to yield a platinum-indium cluster catalyst for a fuel cell.

A method for manufacturing a membrane electrode and gas diffusion layer assembly includes: applying a catalyst ink including an ionomer to a second surface of an electrolyte membrane while conveying a first sheet in which a first surface of the electrolyte membrane is supported by a back sheet; drying the catalyst ink by blowing air vibrated with ultrasonic waves onto a surface of the catalyst ink to produce a second sheet in which a catalyst layer is provided on the second surface of the electrolyte membrane; forming a first roll by winding the second sheet; and producing a third sheet by stacking a gas diffusion layer on the catalyst layer and pressing them in a stacking direction as heating to join the catalyst layer and the gas diffusion layer while conveying the second sheet unwound from the first roll.

A direct isopropanol fuel cell adapted for use in ambient conditions and utilizing as fuel isopropanol and water preferably with isopropanol at relatively high concentrations representing 30% to 90% isopropanol.

Methods of making catalyst-coated membranes are provided. Application of a first catalyst ink to first side of a proton-exchange membrane forms a first electrode coating thereon. Removal of a backing from the proton-exchange membrane exposes a second side of the proton-exchange membrane permitting application of a second catalyst ink to the exposed second side of the proton-exchange membrane to form a second electrode coating thereon. The cathode catalyst ink includes a cathode catalyst, a cathode ionomer, and a cathode solvent. The anode catalyst ink includes anode particles dispersed in an inert, fluorinated, and nonpolar solvent. The anode particles include an anode catalyst, a water electrolysis catalyst, and an anode ionomer.

A cell including: a pair of interconnectors for electrically connecting unit cells; a membrane-electrode assembly disposed between the interconnectors; a pair of current collectors, each of which includes an abutting surface abutting against a corresponding one of the electrode layers and a first base material surface being in contact with a corresponding one of the interconnectors and electrically connecting the corresponding of the electrode layers and the corresponding one of the interconnectors; and elastic bodies biasing the abutting surface of at least one current collector toward a corresponding one of the electrode layers. The elastic bodies includes: a second base material surface being in contact with the first base material surface; and an elastic body protruding portion supporting the abutting surface and protruding from the second base material surface toward the corresponding one of the electrode layers to bias the abutting surface toward the corresponding one of the electrode layers.

A membrane electrode assembly comprises an anode electrode comprising an anode catalyst layer; a cathode electrode comprising a cathode catalyst layer; and a polymer electrolyte membrane interposed between the anode electrode and the cathode electrode; wherein at least one of the anode and cathode catalyst layers comprises a block co-polymer comprising poly(ethylene oxide) and poly(propylene oxide).

The present disclosure relates to a method of manufacturing an electrolyte membrane for fuel cells capable of effectively removing hydrogen and/or air crossing over. Specifically, the method includes coating a slurry including at least an ionomer on a substrate to manufacture an ion transfer layer, manufacturing a laminate including the substrate and the ion transfer layer, and providing a pair of laminates to form an electrolyte membrane, wherein the ion transfer layer has a catalyst region formed at one side thereof based on a width-direction center line thereof, the catalyst region including a catalyst.

Disclosed are an electrolyte membrane for fuel cells that can prevent poisoning of catalysts and a method of producing the same. The electrolyte membrane for fuel cells includes an ion transport layer including an ionomer having proton conductivity, and a catalytic composite dispersed in the ion transport layer, wherein the catalytic composite includes a catalytic particle including a catalytic metal component having an activity of decomposing hydrogen peroxide, and a protective layer formed on at least a part of a surface of the catalytic particle to prevent the ionomer from contacting the catalytic metal component.