Search Results - proton+exchange+water+membrane+electrolyzer+(pemwe)

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Surface Oxophilic Single Atom Decoration of PT Catalyst for Anion Exchange Membrane Fuel Cells (Case No. 2025-263)

Summary: Researchers at UCLA's Department of Chemistry and Biochemistry have developed a novel catalyst design using oxophilic single-atom decorations that enhances the performance and durability of platinum (Pt) catalysts in alkaline exchange membrane fuel cells. Background: Hydrogen fuel cells are a promising alternative to internal combustion...

Published: 6/24/2025 | Inventor(s): Xiangfeng Duan, Yu Huang, Chengzhang Wan

Keywords(s): anion exchange membrane fuel cells (AEMFCs), Catalysts, catalytic hydrogenation, clean energy, clean energy consumption, clean material production, Composite Material, Composite Materials, Construction Materials, Electrocatalyst, electrochemically active surface area, high-durability catalysts, Hydrogen, Hydrogen oxidation reaction, hydrogen oxidation reaction (HOR), hydrogen production, low overpotential catalysis, mass activity, material science, Materials, meta materials, Methane Reformer Hydrogen Production, microarchitectured materials, Nanomaterials, nanostructured materials, Nanotechnology, oxygen oxidation reaction, oxygen reduction reaction (ORR), Platinum group metal catalysts, proton exchange membrane fuel cells (PEMFCs), proton exchange water membrane electrolyzer (PEMWE), Rhodium-decorated Platinum nanowires (SARh-PtNW), specific activity, transition metal catalysts

Category(s): Materials, Materials > Nanotechnology, Materials > Functional Materials, Energy & Environment, Energy & Environment > Energy Generation, Energy & Environment > Energy Efficiency, Energy & Environment > Energy Transmission, Chemical, Chemical > Chemical Processing & Manufacturing, Chemical > Synthesis, Chemical > Catalysts

Non-Noble Metal Catalysts for Effective Electrochemical Acidic Oxygen Evolution (Case No. 2024-114)

Summary: UCLA researchers in the Department of Materials Science and Engineering have developed a novel catalytic material that improves the oxygen evolution reaction for clean hydrogen production. Background: Hydrogen is a promising green alternative to lessen reliance on non-renewable, polluting fuel sources. Current hydrogen production is mainly...

Published: 2/14/2025 | Inventor(s): Yu Huang, Haotian Liu

Keywords(s): acidic water splitting, anode material, green energy, hydrogen evolution reaction, hydrogen production, mass stability, overpotential, oxygen evolution reaction, proton exchange water membrane electrolyzer (PEMWE), Renewable energy sources, spinel oxide, water splitting

Category(s): Energy & Environment, Energy & Environment > Energy Generation, Energy & Environment > Energy Storage, Chemical, Chemical > Catalysts